Fortran#

module codata__api: API.
\(\)

function get_version() → fptr

Get the version.

fptr: character(len=:), pointer

\(\)

module codata__constants_type: Codata constant type
\(\)

type codata_constant_type

Derived type for representing a Codata constant.

name: character(len=64)
value: real(kind=dp)
uncertainty: real(kind=dp)
unit: character(len=32)

print
to_real_sp
to_real_dp
to_real

\(\)

module codata__constants_2010: Codata Constants - Autogenerated
\(\)

Parameters

YEAR_2010: integer(kind=int32), parameter = 2010: Year of release.
LATTICE_SPACING_OF_SILICON_2010: type(codata_constant_type), parameter = codata_constant_type(“{220} lattice spacing of silicon”, 192.0155714e-12_dp, 0.0000032e-12_dp, “m”): {220} lattice spacing of silicon
ALPHA_PARTICLE_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-electron mass ratio”, 7294.2995361_dp, 0.0000029_dp, “”): alpha particle-electron mass ratio
ALPHA_PARTICLE_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass”, 6.64465675e-27_dp, 0.00000029e-27_dp, “kg”): alpha particle mass
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent”, 5.97191967e-10_dp, 0.00000026e-10_dp, “J”): alpha particle mass energy equivalent
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent in MeV”, 3727.379240_dp, 0.000082_dp, “MeV”): alpha particle mass energy equivalent in MeV
ALPHA_PARTICLE_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass in u”, 4.001506179125_dp, 0.000000000062_dp, “u”): alpha particle mass in u
ALPHA_PARTICLE_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle molar mass”, 4.001506179125e-3_dp, 0.000000000062e-3_dp, “kg mol^-1”): alpha particle molar mass
ALPHA_PARTICLE_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-proton mass ratio”, 3.97259968933_dp, 0.00000000036_dp, “”): alpha particle-proton mass ratio
ANGSTROM_STAR_2010: type(codata_constant_type), parameter = codata_constant_type(“Angstrom star”, 1.00001495e-10_dp, 0.00000090e-10_dp, “m”): Angstrom star
ATOMIC_MASS_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant”, 1.660538921e-27_dp, 0.000000073e-27_dp, “kg”): atomic mass constant
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent”, 1.492417954e-10_dp, 0.000000066e-10_dp, “J”): atomic mass constant energy equivalent
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent in MeV”, 931.494061_dp, 0.000021_dp, “MeV”): atomic mass constant energy equivalent in MeV
ATOMIC_MASS_UNIT_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-electron volt relationship”, 931.494061e6_dp, 0.000021e6_dp, “eV”): atomic mass unit-electron volt relationship
ATOMIC_MASS_UNIT_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hartree relationship”, 3.4231776845e7_dp, 0.0000000024e7_dp, “E_h”): atomic mass unit-hartree relationship
ATOMIC_MASS_UNIT_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hertz relationship”, 2.2523427168e23_dp, 0.0000000016e23_dp, “Hz”): atomic mass unit-hertz relationship
ATOMIC_MASS_UNIT_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-inverse meter relationship”, 7.5130066042e14_dp, 0.0000000053e14_dp, “m^-1”): atomic mass unit-inverse meter relationship
ATOMIC_MASS_UNIT_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-joule relationship”, 1.492417954e-10_dp, 0.000000066e-10_dp, “J”): atomic mass unit-joule relationship
ATOMIC_MASS_UNIT_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kelvin relationship”, 1.08095408e13_dp, 0.00000098e13_dp, “K”): atomic mass unit-kelvin relationship
ATOMIC_MASS_UNIT_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kilogram relationship”, 1.660538921e-27_dp, 0.000000073e-27_dp, “kg”): atomic mass unit-kilogram relationship
ATOMIC_UNIT_OF_1ST_HYPERPOLARIZABILITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 1st hyperpolarizability”, 3.206361449e-53_dp, 0.000000071e-53_dp, “C^3 m^3 J^-2”): atomic unit of 1st hyperpolarizability
ATOMIC_UNIT_OF_2ND_HYPERPOLARIZABILITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 2nd hyperpolarizability”, 6.23538054e-65_dp, 0.00000028e-65_dp, “C^4 m^4 J^-3”): atomic unit of 2nd hyperpolarizability
ATOMIC_UNIT_OF_ACTION_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of action”, 1.054571726e-34_dp, 0.000000047e-34_dp, “J s”): atomic unit of action
ATOMIC_UNIT_OF_CHARGE_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge”, 1.602176565e-19_dp, 0.000000035e-19_dp, “C”): atomic unit of charge
ATOMIC_UNIT_OF_CHARGE_DENSITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge density”, 1.081202338e12_dp, 0.000000024e12_dp, “C m^-3”): atomic unit of charge density
ATOMIC_UNIT_OF_CURRENT_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of current”, 6.62361795e-3_dp, 0.00000015e-3_dp, “A”): atomic unit of current
ATOMIC_UNIT_OF_ELECTRIC_DIPOLE_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric dipole mom.”, 8.47835326e-30_dp, 0.00000019e-30_dp, “C m”): atomic unit of electric dipole mom.
ATOMIC_UNIT_OF_ELECTRIC_FIELD_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field”, 5.14220652e11_dp, 0.00000011e11_dp, “V m^-1”): atomic unit of electric field
ATOMIC_UNIT_OF_ELECTRIC_FIELD_GRADIENT_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field gradient”, 9.71736200e21_dp, 0.00000021e21_dp, “V m^-2”): atomic unit of electric field gradient
ATOMIC_UNIT_OF_ELECTRIC_POLARIZABILITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric polarizability”, 1.6487772754e-41_dp, 0.0000000016e-41_dp, “C^2 m^2 J^-1”): atomic unit of electric polarizability
ATOMIC_UNIT_OF_ELECTRIC_POTENTIAL_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric potential”, 27.21138505_dp, 0.00000060_dp, “V”): atomic unit of electric potential
ATOMIC_UNIT_OF_ELECTRIC_QUADRUPOLE_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric quadrupole mom.”, 4.486551331e-40_dp, 0.000000099e-40_dp, “C m^2”): atomic unit of electric quadrupole mom.
ATOMIC_UNIT_OF_ENERGY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of energy”, 4.35974434e-18_dp, 0.00000019e-18_dp, “J”): atomic unit of energy
ATOMIC_UNIT_OF_FORCE_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of force”, 8.23872278e-8_dp, 0.00000036e-8_dp, “N”): atomic unit of force
ATOMIC_UNIT_OF_LENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of length”, 0.52917721092e-10_dp, 0.00000000017e-10_dp, “m”): atomic unit of length
ATOMIC_UNIT_OF_MAG_DIPOLE_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. dipole mom.”, 1.854801936e-23_dp, 0.000000041e-23_dp, “J T^-1”): atomic unit of mag. dipole mom.
ATOMIC_UNIT_OF_MAG_FLUX_DENSITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. flux density”, 2.350517464e5_dp, 0.000000052e5_dp, “T”): atomic unit of mag. flux density
ATOMIC_UNIT_OF_MAGNETIZABILITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of magnetizability”, 7.891036607e-29_dp, 0.000000013e-29_dp, “J T^-2”): atomic unit of magnetizability
ATOMIC_UNIT_OF_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mass”, 9.10938291e-31_dp, 0.00000040e-31_dp, “kg”): atomic unit of mass
ATOMIC_UNIT_OF_MOMUM_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mom.um”, 1.992851740e-24_dp, 0.000000088e-24_dp, “kg m s^-1”): atomic unit of mom.um
ATOMIC_UNIT_OF_PERMITTIVITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of permittivity”, 1.112650056e-10_dp, 0.0_dp, “F m^-1”): atomic unit of permittivity
ATOMIC_UNIT_OF_TIME_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of time”, 2.418884326502e-17_dp, 0.000000000012e-17_dp, “s”): atomic unit of time
ATOMIC_UNIT_OF_VELOCITY_2010: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of velocity”, 2.18769126379e6_dp, 0.00000000071e6_dp, “m s^-1”): atomic unit of velocity
AVOGADRO_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Avogadro constant”, 6.02214129e23_dp, 0.00000027e23_dp, “mol^-1”): Avogadro constant
BOHR_MAGNETON_2010: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton”, 927.400968e-26_dp, 0.000020e-26_dp, “J T^-1”): Bohr magneton
BOHR_MAGNETON_IN_EV_T_2010: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in eV/T”, 5.7883818066e-5_dp, 0.0000000038e-5_dp, “eV T^-1”): Bohr magneton in eV/T
BOHR_MAGNETON_IN_HZ_T_2010: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in Hz/T”, 13.99624555e9_dp, 0.00000031e9_dp, “Hz T^-1”): Bohr magneton in Hz/T
BOHR_MAGNETON_IN_INVERSE_METERS_PER_TESLA_2010: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in inverse meters per tesla”, 46.6864498_dp, 0.0000010_dp, “m^-1 T^-1”): Bohr magneton in inverse meters per tesla
BOHR_MAGNETON_IN_K_T_2010: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in K/T”, 0.67171388_dp, 0.00000061_dp, “K T^-1”): Bohr magneton in K/T
BOHR_RADIUS_2010: type(codata_constant_type), parameter = codata_constant_type(“Bohr radius”, 0.52917721092e-10_dp, 0.00000000017e-10_dp, “m”): Bohr radius
BOLTZMANN_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant”, 1.3806488e-23_dp, 0.0000013e-23_dp, “J K^-1”): Boltzmann constant
BOLTZMANN_CONSTANT_IN_EV_K_2010: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in eV/K”, 8.6173324e-5_dp, 0.0000078e-5_dp, “eV K^-1”): Boltzmann constant in eV/K
BOLTZMANN_CONSTANT_IN_HZ_K_2010: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in Hz/K”, 2.0836618e10_dp, 0.0000019e10_dp, “Hz K^-1”): Boltzmann constant in Hz/K
BOLTZMANN_CONSTANT_IN_INVERSE_METERS_PER_KELVIN_2010: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in inverse meters per kelvin”, 69.503476_dp, 0.000063_dp, “m^-1 K^-1”): Boltzmann constant in inverse meters per kelvin
CHARACTERISTIC_IMPEDANCE_OF_VACUUM_2010: type(codata_constant_type), parameter = codata_constant_type(“characteristic impedance of vacuum”, 376.730313461_dp, 0.0_dp, “ohm”): characteristic impedance of vacuum
CLASSICAL_ELECTRON_RADIUS_2010: type(codata_constant_type), parameter = codata_constant_type(“classical electron radius”, 2.8179403267e-15_dp, 0.0000000027e-15_dp, “m”): classical electron radius
COMPTON_WAVELENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“Compton wavelength”, 2.4263102389e-12_dp, 0.0000000016e-12_dp, “m”): Compton wavelength
COMPTON_WAVELENGTH_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“Compton wavelength over 2 pi”, 386.15926800e-15_dp, 0.00000025e-15_dp, “m”): Compton wavelength over 2 pi
CONDUCTANCE_QUANTUM_2010: type(codata_constant_type), parameter = codata_constant_type(“conductance quantum”, 7.7480917346e-5_dp, 0.0000000025e-5_dp, “S”): conductance quantum
CONVENTIONAL_VALUE_OF_JOSEPHSON_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“conventional value of Josephson constant”, 483597.9e9_dp, 0.0_dp, “Hz V^-1”): conventional value of Josephson constant
CONVENTIONAL_VALUE_OF_VON_KLITZING_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“conventional value of von Klitzing constant”, 25812.807_dp, 0.0_dp, “ohm”): conventional value of von Klitzing constant
CU_X_UNIT_2010: type(codata_constant_type), parameter = codata_constant_type(“Cu x unit”, 1.00207697e-13_dp, 0.00000028e-13_dp, “m”): Cu x unit
DEUTERON_ELECTRON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mag. mom. ratio”, -4.664345537e-4_dp, 0.000000039e-4_dp, “”): deuteron-electron mag. mom. ratio
DEUTERON_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mass ratio”, 3670.4829652_dp, 0.0000015_dp, “”): deuteron-electron mass ratio
DEUTERON_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron g factor”, 0.8574382308_dp, 0.0000000072_dp, “”): deuteron g factor
DEUTERON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom.”, 0.433073489e-26_dp, 0.000000010e-26_dp, “J T^-1”): deuteron mag. mom.
DEUTERON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to Bohr magneton ratio”, 0.4669754556e-3_dp, 0.0000000039e-3_dp, “”): deuteron mag. mom. to Bohr magneton ratio
DEUTERON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to nuclear magneton ratio”, 0.8574382308_dp, 0.0000000072_dp, “”): deuteron mag. mom. to nuclear magneton ratio
DEUTERON_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass”, 3.34358348e-27_dp, 0.00000015e-27_dp, “kg”): deuteron mass
DEUTERON_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent”, 3.00506297e-10_dp, 0.00000013e-10_dp, “J”): deuteron mass energy equivalent
DEUTERON_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent in MeV”, 1875.612859_dp, 0.000041_dp, “MeV”): deuteron mass energy equivalent in MeV
DEUTERON_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass in u”, 2.013553212712_dp, 0.000000000077_dp, “u”): deuteron mass in u
DEUTERON_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron molar mass”, 2.013553212712e-3_dp, 0.000000000077e-3_dp, “kg mol^-1”): deuteron molar mass
DEUTERON_NEUTRON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron-neutron mag. mom. ratio”, -0.44820652_dp, 0.00000011_dp, “”): deuteron-neutron mag. mom. ratio
DEUTERON_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mag. mom. ratio”, 0.3070122070_dp, 0.0000000024_dp, “”): deuteron-proton mag. mom. ratio
DEUTERON_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mass ratio”, 1.99900750097_dp, 0.00000000018_dp, “”): deuteron-proton mass ratio
DEUTERON_RMS_CHARGE_RADIUS_2010: type(codata_constant_type), parameter = codata_constant_type(“deuteron rms charge radius”, 2.1424e-15_dp, 0.0021e-15_dp, “m”): deuteron rms charge radius
ELECTRIC_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“electric constant”, 8.854187817e-12_dp, 0.0_dp, “F m^-1”): electric constant
ELECTRON_CHARGE_TO_MASS_QUOTIENT_2010: type(codata_constant_type), parameter = codata_constant_type(“electron charge to mass quotient”, -1.758820088e11_dp, 0.000000039e11_dp, “C kg^-1”): electron charge to mass quotient
ELECTRON_DEUTERON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mag. mom. ratio”, -2143.923498_dp, 0.000018_dp, “”): electron-deuteron mag. mom. ratio
ELECTRON_DEUTERON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mass ratio”, 2.7244371095e-4_dp, 0.0000000011e-4_dp, “”): electron-deuteron mass ratio
ELECTRON_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“electron g factor”, -2.00231930436153_dp, 0.00000000000053_dp, “”): electron g factor
ELECTRON_GYROMAG_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio”, 1.760859708e11_dp, 0.000000039e11_dp, “s^-1 T^-1”): electron gyromag. ratio
ELECTRON_GYROMAG_RATIO_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio over 2 pi”, 28024.95266_dp, 0.00062_dp, “MHz T^-1”): electron gyromag. ratio over 2 pi
ELECTRON_HELION_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-helion mass ratio”, 1.8195430761e-4_dp, 0.0000000017e-4_dp, “”): electron-helion mass ratio
ELECTRON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom.”, -928.476430e-26_dp, 0.000021e-26_dp, “J T^-1”): electron mag. mom.
ELECTRON_MAG_MOM_ANOMALY_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. anomaly”, 1.15965218076e-3_dp, 0.00000000027e-3_dp, “”): electron mag. mom. anomaly
ELECTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to Bohr magneton ratio”, -1.00115965218076_dp, 0.00000000000027_dp, “”): electron mag. mom. to Bohr magneton ratio
ELECTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to nuclear magneton ratio”, -1838.28197090_dp, 0.00000075_dp, “”): electron mag. mom. to nuclear magneton ratio
ELECTRON_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mass”, 9.10938291e-31_dp, 0.00000040e-31_dp, “kg”): electron mass
ELECTRON_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent”, 8.18710506e-14_dp, 0.00000036e-14_dp, “J”): electron mass energy equivalent
ELECTRON_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent in MeV”, 0.510998928_dp, 0.000000011_dp, “MeV”): electron mass energy equivalent in MeV
ELECTRON_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“electron mass in u”, 5.4857990946e-4_dp, 0.0000000022e-4_dp, “u”): electron mass in u
ELECTRON_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“electron molar mass”, 5.4857990946e-7_dp, 0.0000000022e-7_dp, “kg mol^-1”): electron molar mass
ELECTRON_MUON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mag. mom. ratio”, 206.7669896_dp, 0.0000052_dp, “”): electron-muon mag. mom. ratio
ELECTRON_MUON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mass ratio”, 4.83633166e-3_dp, 0.00000012e-3_dp, “”): electron-muon mass ratio
ELECTRON_NEUTRON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mag. mom. ratio”, 960.92050_dp, 0.00023_dp, “”): electron-neutron mag. mom. ratio
ELECTRON_NEUTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mass ratio”, 5.4386734461e-4_dp, 0.0000000032e-4_dp, “”): electron-neutron mass ratio
ELECTRON_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mag. mom. ratio”, -658.2106848_dp, 0.0000054_dp, “”): electron-proton mag. mom. ratio
ELECTRON_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mass ratio”, 5.4461702178e-4_dp, 0.0000000022e-4_dp, “”): electron-proton mass ratio
ELECTRON_TAU_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-tau mass ratio”, 2.87592e-4_dp, 0.00026e-4_dp, “”): electron-tau mass ratio
ELECTRON_TO_ALPHA_PARTICLE_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron to alpha particle mass ratio”, 1.37093355578e-4_dp, 0.00000000055e-4_dp, “”): electron to alpha particle mass ratio
ELECTRON_TO_SHIELDED_HELION_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded helion mag. mom. ratio”, 864.058257_dp, 0.000010_dp, “”): electron to shielded helion mag. mom. ratio
ELECTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded proton mag. mom. ratio”, -658.2275971_dp, 0.0000072_dp, “”): electron to shielded proton mag. mom. ratio
ELECTRON_TRITON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“electron-triton mass ratio”, 1.8192000653e-4_dp, 0.0000000017e-4_dp, “”): electron-triton mass ratio
ELECTRON_VOLT_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt”, 1.602176565e-19_dp, 0.000000035e-19_dp, “J”): electron volt
ELECTRON_VOLT_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-atomic mass unit relationship”, 1.073544150e-9_dp, 0.000000024e-9_dp, “u”): electron volt-atomic mass unit relationship
ELECTRON_VOLT_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hartree relationship”, 3.674932379e-2_dp, 0.000000081e-2_dp, “E_h”): electron volt-hartree relationship
ELECTRON_VOLT_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hertz relationship”, 2.417989348e14_dp, 0.000000053e14_dp, “Hz”): electron volt-hertz relationship
ELECTRON_VOLT_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-inverse meter relationship”, 8.06554429e5_dp, 0.00000018e5_dp, “m^-1”): electron volt-inverse meter relationship
ELECTRON_VOLT_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-joule relationship”, 1.602176565e-19_dp, 0.000000035e-19_dp, “J”): electron volt-joule relationship
ELECTRON_VOLT_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kelvin relationship”, 1.1604519e4_dp, 0.0000011e4_dp, “K”): electron volt-kelvin relationship
ELECTRON_VOLT_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kilogram relationship”, 1.782661845e-36_dp, 0.000000039e-36_dp, “kg”): electron volt-kilogram relationship
ELEMENTARY_CHARGE_2010: type(codata_constant_type), parameter = codata_constant_type(“elementary charge”, 1.602176565e-19_dp, 0.000000035e-19_dp, “C”): elementary charge
ELEMENTARY_CHARGE_OVER_H_2010: type(codata_constant_type), parameter = codata_constant_type(“elementary charge over h”, 2.417989348e14_dp, 0.000000053e14_dp, “A J^-1”): elementary charge over h
FARADAY_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Faraday constant”, 96485.3365_dp, 0.0021_dp, “C mol^-1”): Faraday constant
FARADAY_CONSTANT_FOR_CONVENTIONAL_ELECTRIC_CURRENT_2010: type(codata_constant_type), parameter = codata_constant_type(“Faraday constant for conventional electric current”, 96485.3321_dp, 0.0043_dp, “C_90 mol^-1”): Faraday constant for conventional electric current
FERMI_COUPLING_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Fermi coupling constant”, 1.166364e-5_dp, 0.000005e-5_dp, “GeV^-2”): Fermi coupling constant
FINE_STRUCTURE_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“fine-structure constant”, 7.2973525698e-3_dp, 0.0000000024e-3_dp, “”): fine-structure constant
FIRST_RADIATION_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant”, 3.74177153e-16_dp, 0.00000017e-16_dp, “W m^2”): first radiation constant
FIRST_RADIATION_CONSTANT_FOR_SPECTRAL_RADIANCE_2010: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant for spectral radiance”, 1.191042869e-16_dp, 0.000000053e-16_dp, “W m^2 sr^-1”): first radiation constant for spectral radiance
HARTREE_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-atomic mass unit relationship”, 2.9212623246e-8_dp, 0.0000000021e-8_dp, “u”): hartree-atomic mass unit relationship
HARTREE_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-electron volt relationship”, 27.21138505_dp, 0.00000060_dp, “eV”): hartree-electron volt relationship
HARTREE_ENERGY_2010: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy”, 4.35974434e-18_dp, 0.00000019e-18_dp, “J”): Hartree energy
HARTREE_ENERGY_IN_EV_2010: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy in eV”, 27.21138505_dp, 0.00000060_dp, “eV”): Hartree energy in eV
HARTREE_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-hertz relationship”, 6.579683920729e15_dp, 0.000000000033e15_dp, “Hz”): hartree-hertz relationship
HARTREE_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-inverse meter relationship”, 2.194746313708e7_dp, 0.000000000011e7_dp, “m^-1”): hartree-inverse meter relationship
HARTREE_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-joule relationship”, 4.35974434e-18_dp, 0.00000019e-18_dp, “J”): hartree-joule relationship
HARTREE_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-kelvin relationship”, 3.1577504e5_dp, 0.0000029e5_dp, “K”): hartree-kelvin relationship
HARTREE_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hartree-kilogram relationship”, 4.85086979e-35_dp, 0.00000021e-35_dp, “kg”): hartree-kilogram relationship
HELION_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“helion-electron mass ratio”, 5495.8852754_dp, 0.0000050_dp, “”): helion-electron mass ratio
HELION_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“helion g factor”, -4.255250613_dp, 0.000000050_dp, “”): helion g factor
HELION_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom.”, -1.074617486e-26_dp, 0.000000027e-26_dp, “J T^-1”): helion mag. mom.
HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to Bohr magneton ratio”, -1.158740958e-3_dp, 0.000000014e-3_dp, “”): helion mag. mom. to Bohr magneton ratio
HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to nuclear magneton ratio”, -2.127625306_dp, 0.000000025_dp, “”): helion mag. mom. to nuclear magneton ratio
HELION_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mass”, 5.00641234e-27_dp, 0.00000022e-27_dp, “kg”): helion mass
HELION_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent”, 4.49953902e-10_dp, 0.00000020e-10_dp, “J”): helion mass energy equivalent
HELION_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent in MeV”, 2808.391482_dp, 0.000062_dp, “MeV”): helion mass energy equivalent in MeV
HELION_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“helion mass in u”, 3.0149322468_dp, 0.0000000025_dp, “u”): helion mass in u
HELION_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“helion molar mass”, 3.0149322468e-3_dp, 0.0000000025e-3_dp, “kg mol^-1”): helion molar mass
HELION_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“helion-proton mass ratio”, 2.9931526707_dp, 0.0000000025_dp, “”): helion-proton mass ratio
HERTZ_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-atomic mass unit relationship”, 4.4398216689e-24_dp, 0.0000000031e-24_dp, “u”): hertz-atomic mass unit relationship
HERTZ_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-electron volt relationship”, 4.135667516e-15_dp, 0.000000091e-15_dp, “eV”): hertz-electron volt relationship
HERTZ_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-hartree relationship”, 1.5198298460045e-16_dp, 0.0000000000076e-16_dp, “E_h”): hertz-hartree relationship
HERTZ_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-inverse meter relationship”, 3.335640951e-9_dp, 0.0_dp, “m^-1”): hertz-inverse meter relationship
HERTZ_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-joule relationship”, 6.62606957e-34_dp, 0.00000029e-34_dp, “J”): hertz-joule relationship
HERTZ_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-kelvin relationship”, 4.7992434e-11_dp, 0.0000044e-11_dp, “K”): hertz-kelvin relationship
HERTZ_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“hertz-kilogram relationship”, 7.37249668e-51_dp, 0.00000033e-51_dp, “kg”): hertz-kilogram relationship
INVERSE_FINE_STRUCTURE_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse fine-structure constant”, 137.035999074_dp, 0.000000044_dp, “”): inverse fine-structure constant
INVERSE_METER_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-atomic mass unit relationship”, 1.33102505120e-15_dp, 0.00000000094e-15_dp, “u”): inverse meter-atomic mass unit relationship
INVERSE_METER_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-electron volt relationship”, 1.239841930e-6_dp, 0.000000027e-6_dp, “eV”): inverse meter-electron volt relationship
INVERSE_METER_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hartree relationship”, 4.556335252755e-8_dp, 0.000000000023e-8_dp, “E_h”): inverse meter-hartree relationship
INVERSE_METER_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hertz relationship”, 299792458_dp, 0.0_dp, “Hz”): inverse meter-hertz relationship
INVERSE_METER_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-joule relationship”, 1.986445684e-25_dp, 0.000000088e-25_dp, “J”): inverse meter-joule relationship
INVERSE_METER_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kelvin relationship”, 1.4387770e-2_dp, 0.0000013e-2_dp, “K”): inverse meter-kelvin relationship
INVERSE_METER_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kilogram relationship”, 2.210218902e-42_dp, 0.000000098e-42_dp, “kg”): inverse meter-kilogram relationship
INVERSE_OF_CONDUCTANCE_QUANTUM_2010: type(codata_constant_type), parameter = codata_constant_type(“inverse of conductance quantum”, 12906.4037217_dp, 0.0000042_dp, “ohm”): inverse of conductance quantum
JOSEPHSON_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Josephson constant”, 483597.870e9_dp, 0.011e9_dp, “Hz V^-1”): Josephson constant
JOULE_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-atomic mass unit relationship”, 6.70053585e9_dp, 0.00000030e9_dp, “u”): joule-atomic mass unit relationship
JOULE_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-electron volt relationship”, 6.24150934e18_dp, 0.00000014e18_dp, “eV”): joule-electron volt relationship
JOULE_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-hartree relationship”, 2.29371248e17_dp, 0.00000010e17_dp, “E_h”): joule-hartree relationship
JOULE_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-hertz relationship”, 1.509190311e33_dp, 0.000000067e33_dp, “Hz”): joule-hertz relationship
JOULE_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-inverse meter relationship”, 5.03411701e24_dp, 0.00000022e24_dp, “m^-1”): joule-inverse meter relationship
JOULE_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-kelvin relationship”, 7.2429716e22_dp, 0.0000066e22_dp, “K”): joule-kelvin relationship
JOULE_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“joule-kilogram relationship”, 1.112650056e-17_dp, 0.0_dp, “kg”): joule-kilogram relationship
KELVIN_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-atomic mass unit relationship”, 9.2510868e-14_dp, 0.0000084e-14_dp, “u”): kelvin-atomic mass unit relationship
KELVIN_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-electron volt relationship”, 8.6173324e-5_dp, 0.0000078e-5_dp, “eV”): kelvin-electron volt relationship
KELVIN_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hartree relationship”, 3.1668114e-6_dp, 0.0000029e-6_dp, “E_h”): kelvin-hartree relationship
KELVIN_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hertz relationship”, 2.0836618e10_dp, 0.0000019e10_dp, “Hz”): kelvin-hertz relationship
KELVIN_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-inverse meter relationship”, 69.503476_dp, 0.000063_dp, “m^-1”): kelvin-inverse meter relationship
KELVIN_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-joule relationship”, 1.3806488e-23_dp, 0.0000013e-23_dp, “J”): kelvin-joule relationship
KELVIN_KILOGRAM_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kelvin-kilogram relationship”, 1.5361790e-40_dp, 0.0000014e-40_dp, “kg”): kelvin-kilogram relationship
KILOGRAM_ATOMIC_MASS_UNIT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-atomic mass unit relationship”, 6.02214129e26_dp, 0.00000027e26_dp, “u”): kilogram-atomic mass unit relationship
KILOGRAM_ELECTRON_VOLT_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-electron volt relationship”, 5.60958885e35_dp, 0.00000012e35_dp, “eV”): kilogram-electron volt relationship
KILOGRAM_HARTREE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hartree relationship”, 2.061485968e34_dp, 0.000000091e34_dp, “E_h”): kilogram-hartree relationship
KILOGRAM_HERTZ_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hertz relationship”, 1.356392608e50_dp, 0.000000060e50_dp, “Hz”): kilogram-hertz relationship
KILOGRAM_INVERSE_METER_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-inverse meter relationship”, 4.52443873e41_dp, 0.00000020e41_dp, “m^-1”): kilogram-inverse meter relationship
KILOGRAM_JOULE_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-joule relationship”, 8.987551787e16_dp, 0.0_dp, “J”): kilogram-joule relationship
KILOGRAM_KELVIN_RELATIONSHIP_2010: type(codata_constant_type), parameter = codata_constant_type(“kilogram-kelvin relationship”, 6.5096582e39_dp, 0.0000059e39_dp, “K”): kilogram-kelvin relationship
LATTICE_PARAMETER_OF_SILICON_2010: type(codata_constant_type), parameter = codata_constant_type(“lattice parameter of silicon”, 543.1020504e-12_dp, 0.0000089e-12_dp, “m”): lattice parameter of silicon
LOSCHMIDT_CONSTANT_273_15_K_100_KPA_2010: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 100 kPa)”, 2.6516462e25_dp, 0.0000024e25_dp, “m^-3”): Loschmidt constant (273.15 K, 100 kPa)
LOSCHMIDT_CONSTANT_273_15_K_101_325_KPA_2010: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 101.325 kPa)”, 2.6867805e25_dp, 0.0000024e25_dp, “m^-3”): Loschmidt constant (273.15 K, 101.325 kPa)
MAG_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“mag. constant”, 12.566370614e-7_dp, 0.0_dp, “N A^-2”): mag. constant
MAG_FLUX_QUANTUM_2010: type(codata_constant_type), parameter = codata_constant_type(“mag. flux quantum”, 2.067833758e-15_dp, 0.000000046e-15_dp, “Wb”): mag. flux quantum
MOLAR_GAS_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“molar gas constant”, 8.3144621_dp, 0.0000075_dp, “J mol^-1 K^-1”): molar gas constant
MOLAR_MASS_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“molar mass constant”, 1e-3_dp, 0.0_dp, “kg mol^-1”): molar mass constant
MOLAR_MASS_OF_CARBON_12_2010: type(codata_constant_type), parameter = codata_constant_type(“molar mass of carbon-12”, 12e-3_dp, 0.0_dp, “kg mol^-1”): molar mass of carbon-12
MOLAR_PLANCK_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“molar Planck constant”, 3.9903127176e-10_dp, 0.0000000028e-10_dp, “J s mol^-1”): molar Planck constant
MOLAR_PLANCK_CONSTANT_TIMES_C_2010: type(codata_constant_type), parameter = codata_constant_type(“molar Planck constant times c”, 0.119626565779_dp, 0.000000000084_dp, “J m mol^-1”): molar Planck constant times c
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_100_KPA_2010: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 100 kPa)”, 22.710953e-3_dp, 0.000021e-3_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 100 kPa)
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_101_325_KPA_2010: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 101.325 kPa)”, 22.413968e-3_dp, 0.000020e-3_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 101.325 kPa)
MOLAR_VOLUME_OF_SILICON_2010: type(codata_constant_type), parameter = codata_constant_type(“molar volume of silicon”, 12.05883301e-6_dp, 0.00000080e-6_dp, “m^3 mol^-1”): molar volume of silicon
MO_X_UNIT_2010: type(codata_constant_type), parameter = codata_constant_type(“Mo x unit”, 1.00209952e-13_dp, 0.00000053e-13_dp, “m”): Mo x unit
MUON_COMPTON_WAVELENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“muon Compton wavelength”, 11.73444103e-15_dp, 0.00000030e-15_dp, “m”): muon Compton wavelength
MUON_COMPTON_WAVELENGTH_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“muon Compton wavelength over 2 pi”, 1.867594294e-15_dp, 0.000000047e-15_dp, “m”): muon Compton wavelength over 2 pi
MUON_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon-electron mass ratio”, 206.7682843_dp, 0.0000052_dp, “”): muon-electron mass ratio
MUON_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“muon g factor”, -2.0023318418_dp, 0.0000000013_dp, “”): muon g factor
MUON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom.”, -4.49044807e-26_dp, 0.00000015e-26_dp, “J T^-1”): muon mag. mom.
MUON_MAG_MOM_ANOMALY_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. anomaly”, 1.16592091e-3_dp, 0.00000063e-3_dp, “”): muon mag. mom. anomaly
MUON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to Bohr magneton ratio”, -4.84197044e-3_dp, 0.00000012e-3_dp, “”): muon mag. mom. to Bohr magneton ratio
MUON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to nuclear magneton ratio”, -8.89059697_dp, 0.00000022_dp, “”): muon mag. mom. to nuclear magneton ratio
MUON_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mass”, 1.883531475e-28_dp, 0.000000096e-28_dp, “kg”): muon mass
MUON_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent”, 1.692833667e-11_dp, 0.000000086e-11_dp, “J”): muon mass energy equivalent
MUON_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent in MeV”, 105.6583715_dp, 0.0000035_dp, “MeV”): muon mass energy equivalent in MeV
MUON_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“muon mass in u”, 0.1134289267_dp, 0.0000000029_dp, “u”): muon mass in u
MUON_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“muon molar mass”, 0.1134289267e-3_dp, 0.0000000029e-3_dp, “kg mol^-1”): muon molar mass
MUON_NEUTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon-neutron mass ratio”, 0.1124545177_dp, 0.0000000028_dp, “”): muon-neutron mass ratio
MUON_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mag. mom. ratio”, -3.183345107_dp, 0.000000084_dp, “”): muon-proton mag. mom. ratio
MUON_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mass ratio”, 0.1126095272_dp, 0.0000000028_dp, “”): muon-proton mass ratio
MUON_TAU_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“muon-tau mass ratio”, 5.94649e-2_dp, 0.00054e-2_dp, “”): muon-tau mass ratio
NATURAL_UNIT_OF_ACTION_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action”, 1.054571726e-34_dp, 0.000000047e-34_dp, “J s”): natural unit of action
NATURAL_UNIT_OF_ACTION_IN_EV_S_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action in eV s”, 6.58211928e-16_dp, 0.00000015e-16_dp, “eV s”): natural unit of action in eV s
NATURAL_UNIT_OF_ENERGY_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy”, 8.18710506e-14_dp, 0.00000036e-14_dp, “J”): natural unit of energy
NATURAL_UNIT_OF_ENERGY_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy in MeV”, 0.510998928_dp, 0.000000011_dp, “MeV”): natural unit of energy in MeV
NATURAL_UNIT_OF_LENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of length”, 386.15926800e-15_dp, 0.00000025e-15_dp, “m”): natural unit of length
NATURAL_UNIT_OF_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mass”, 9.10938291e-31_dp, 0.00000040e-31_dp, “kg”): natural unit of mass
NATURAL_UNIT_OF_MOMUM_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mom.um”, 2.73092429e-22_dp, 0.00000012e-22_dp, “kg m s^-1”): natural unit of mom.um
NATURAL_UNIT_OF_MOMUM_IN_MEV_C_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mom.um in MeV/c”, 0.510998928_dp, 0.000000011_dp, “MeV/c”): natural unit of mom.um in MeV/c
NATURAL_UNIT_OF_TIME_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of time”, 1.28808866833e-21_dp, 0.00000000083e-21_dp, “s”): natural unit of time
NATURAL_UNIT_OF_VELOCITY_2010: type(codata_constant_type), parameter = codata_constant_type(“natural unit of velocity”, 299792458_dp, 0.0_dp, “m s^-1”): natural unit of velocity
NEUTRON_COMPTON_WAVELENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron Compton wavelength”, 1.3195909068e-15_dp, 0.0000000011e-15_dp, “m”): neutron Compton wavelength
NEUTRON_COMPTON_WAVELENGTH_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron Compton wavelength over 2 pi”, 0.21001941568e-15_dp, 0.00000000017e-15_dp, “m”): neutron Compton wavelength over 2 pi
NEUTRON_ELECTRON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mag. mom. ratio”, 1.04066882e-3_dp, 0.00000025e-3_dp, “”): neutron-electron mag. mom. ratio
NEUTRON_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mass ratio”, 1838.6836605_dp, 0.0000011_dp, “”): neutron-electron mass ratio
NEUTRON_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron g factor”, -3.82608545_dp, 0.00000090_dp, “”): neutron g factor
NEUTRON_GYROMAG_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio”, 1.83247179e8_dp, 0.00000043e8_dp, “s^-1 T^-1”): neutron gyromag. ratio
NEUTRON_GYROMAG_RATIO_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio over 2 pi”, 29.1646943_dp, 0.0000069_dp, “MHz T^-1”): neutron gyromag. ratio over 2 pi
NEUTRON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom.”, -0.96623647e-26_dp, 0.00000023e-26_dp, “J T^-1”): neutron mag. mom.
NEUTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to Bohr magneton ratio”, -1.04187563e-3_dp, 0.00000025e-3_dp, “”): neutron mag. mom. to Bohr magneton ratio
NEUTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to nuclear magneton ratio”, -1.91304272_dp, 0.00000045_dp, “”): neutron mag. mom. to nuclear magneton ratio
NEUTRON_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mass”, 1.674927351e-27_dp, 0.000000074e-27_dp, “kg”): neutron mass
NEUTRON_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent”, 1.505349631e-10_dp, 0.000000066e-10_dp, “J”): neutron mass energy equivalent
NEUTRON_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent in MeV”, 939.565379_dp, 0.000021_dp, “MeV”): neutron mass energy equivalent in MeV
NEUTRON_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron mass in u”, 1.00866491600_dp, 0.00000000043_dp, “u”): neutron mass in u
NEUTRON_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron molar mass”, 1.00866491600e-3_dp, 0.00000000043e-3_dp, “kg mol^-1”): neutron molar mass
NEUTRON_MUON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-muon mass ratio”, 8.89248400_dp, 0.00000022_dp, “”): neutron-muon mass ratio
NEUTRON_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mag. mom. ratio”, -0.68497934_dp, 0.00000016_dp, “”): neutron-proton mag. mom. ratio
NEUTRON_PROTON_MASS_DIFFERENCE_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference”, 2.30557392e-30_dp, 0.00000076e-30_dp, “”): neutron-proton mass difference
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent”, 2.07214650e-13_dp, 0.00000068e-13_dp, “”): neutron-proton mass difference energy equivalent
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent in MeV”, 1.29333217_dp, 0.00000042_dp, “”): neutron-proton mass difference energy equivalent in MeV
NEUTRON_PROTON_MASS_DIFFERENCE_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference in u”, 0.00138844919_dp, 0.00000000045_dp, “”): neutron-proton mass difference in u
NEUTRON_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass ratio”, 1.00137841917_dp, 0.00000000045_dp, “”): neutron-proton mass ratio
NEUTRON_TAU_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron-tau mass ratio”, 0.528790_dp, 0.000048_dp, “”): neutron-tau mass ratio
NEUTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“neutron to shielded proton mag. mom. ratio”, -0.68499694_dp, 0.00000016_dp, “”): neutron to shielded proton mag. mom. ratio
NEWTONIAN_CONSTANT_OF_GRAVITATION_2010: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation”, 6.67384e-11_dp, 0.00080e-11_dp, “m^3 kg^-1 s^-2”): Newtonian constant of gravitation
NEWTONIAN_CONSTANT_OF_GRAVITATION_OVER_H_BAR_C_2010: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation over h-bar c”, 6.70837e-39_dp, 0.00080e-39_dp, “(GeV/c^2)^-2”): Newtonian constant of gravitation over h-bar c
NUCLEAR_MAGNETON_2010: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton”, 5.05078353e-27_dp, 0.00000011e-27_dp, “J T^-1”): nuclear magneton
NUCLEAR_MAGNETON_IN_EV_T_2010: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in eV/T”, 3.1524512605e-8_dp, 0.0000000022e-8_dp, “eV T^-1”): nuclear magneton in eV/T
NUCLEAR_MAGNETON_IN_INVERSE_METERS_PER_TESLA_2010: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in inverse meters per tesla”, 2.542623527e-2_dp, 0.000000056e-2_dp, “m^-1 T^-1”): nuclear magneton in inverse meters per tesla
NUCLEAR_MAGNETON_IN_K_T_2010: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in K/T”, 3.6582682e-4_dp, 0.0000033e-4_dp, “K T^-1”): nuclear magneton in K/T
NUCLEAR_MAGNETON_IN_MHZ_T_2010: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in MHz/T”, 7.62259357_dp, 0.00000017_dp, “MHz T^-1”): nuclear magneton in MHz/T
PLANCK_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck constant”, 6.62606957e-34_dp, 0.00000029e-34_dp, “J s”): Planck constant
PLANCK_CONSTANT_IN_EV_S_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck constant in eV s”, 4.135667516e-15_dp, 0.000000091e-15_dp, “eV s”): Planck constant in eV s
PLANCK_CONSTANT_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck constant over 2 pi”, 1.054571726e-34_dp, 0.000000047e-34_dp, “J s”): Planck constant over 2 pi
PLANCK_CONSTANT_OVER_2_PI_IN_EV_S_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck constant over 2 pi in eV s”, 6.58211928e-16_dp, 0.00000015e-16_dp, “eV s”): Planck constant over 2 pi in eV s
PLANCK_CONSTANT_OVER_2_PI_TIMES_C_IN_MEV_FM_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck constant over 2 pi times c in MeV fm”, 197.3269718_dp, 0.0000044_dp, “MeV fm”): Planck constant over 2 pi times c in MeV fm
PLANCK_LENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck length”, 1.616199e-35_dp, 0.000097e-35_dp, “m”): Planck length
PLANCK_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck mass”, 2.17651e-8_dp, 0.00013e-8_dp, “kg”): Planck mass
PLANCK_MASS_ENERGY_EQUIVALENT_IN_GEV_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck mass energy equivalent in GeV”, 1.220932e19_dp, 0.000073e19_dp, “GeV”): Planck mass energy equivalent in GeV
PLANCK_TEMPERATURE_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck temperature”, 1.416833e32_dp, 0.000085e32_dp, “K”): Planck temperature
PLANCK_TIME_2010: type(codata_constant_type), parameter = codata_constant_type(“Planck time”, 5.39106e-44_dp, 0.00032e-44_dp, “s”): Planck time
PROTON_CHARGE_TO_MASS_QUOTIENT_2010: type(codata_constant_type), parameter = codata_constant_type(“proton charge to mass quotient”, 9.57883358e7_dp, 0.00000021e7_dp, “C kg^-1”): proton charge to mass quotient
PROTON_COMPTON_WAVELENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“proton Compton wavelength”, 1.32140985623e-15_dp, 0.00000000094e-15_dp, “m”): proton Compton wavelength
PROTON_COMPTON_WAVELENGTH_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“proton Compton wavelength over 2 pi”, 0.21030891047e-15_dp, 0.00000000015e-15_dp, “m”): proton Compton wavelength over 2 pi
PROTON_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton-electron mass ratio”, 1836.15267245_dp, 0.00000075_dp, “”): proton-electron mass ratio
PROTON_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“proton g factor”, 5.585694713_dp, 0.000000046_dp, “”): proton g factor
PROTON_GYROMAG_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio”, 2.675222005e8_dp, 0.000000063e8_dp, “s^-1 T^-1”): proton gyromag. ratio
PROTON_GYROMAG_RATIO_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio over 2 pi”, 42.5774806_dp, 0.0000010_dp, “MHz T^-1”): proton gyromag. ratio over 2 pi
PROTON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom.”, 1.410606743e-26_dp, 0.000000033e-26_dp, “J T^-1”): proton mag. mom.
PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to Bohr magneton ratio”, 1.521032210e-3_dp, 0.000000012e-3_dp, “”): proton mag. mom. to Bohr magneton ratio
PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to nuclear magneton ratio”, 2.792847356_dp, 0.000000023_dp, “”): proton mag. mom. to nuclear magneton ratio
PROTON_MAG_SHIELDING_CORRECTION_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mag. shielding correction”, 25.694e-6_dp, 0.014e-6_dp, “”): proton mag. shielding correction
PROTON_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mass”, 1.672621777e-27_dp, 0.000000074e-27_dp, “kg”): proton mass
PROTON_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent”, 1.503277484e-10_dp, 0.000000066e-10_dp, “J”): proton mass energy equivalent
PROTON_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent in MeV”, 938.272046_dp, 0.000021_dp, “MeV”): proton mass energy equivalent in MeV
PROTON_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“proton mass in u”, 1.007276466812_dp, 0.000000000090_dp, “u”): proton mass in u
PROTON_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“proton molar mass”, 1.007276466812e-3_dp, 0.000000000090e-3_dp, “kg mol^-1”): proton molar mass
PROTON_MUON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton-muon mass ratio”, 8.88024331_dp, 0.00000022_dp, “”): proton-muon mass ratio
PROTON_NEUTRON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mag. mom. ratio”, -1.45989806_dp, 0.00000034_dp, “”): proton-neutron mag. mom. ratio
PROTON_NEUTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mass ratio”, 0.99862347826_dp, 0.00000000045_dp, “”): proton-neutron mass ratio
PROTON_RMS_CHARGE_RADIUS_2010: type(codata_constant_type), parameter = codata_constant_type(“proton rms charge radius”, 0.8775e-15_dp, 0.0051e-15_dp, “m”): proton rms charge radius
PROTON_TAU_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“proton-tau mass ratio”, 0.528063_dp, 0.000048_dp, “”): proton-tau mass ratio
QUANTUM_OF_CIRCULATION_2010: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation”, 3.6369475520e-4_dp, 0.0000000024e-4_dp, “m^2 s^-1”): quantum of circulation
QUANTUM_OF_CIRCULATION_TIMES_2_2010: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation times 2”, 7.2738951040e-4_dp, 0.0000000047e-4_dp, “m^2 s^-1”): quantum of circulation times 2
RYDBERG_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant”, 10973731.568539_dp, 0.000055_dp, “m^-1”): Rydberg constant
RYDBERG_CONSTANT_TIMES_C_IN_HZ_2010: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times c in Hz”, 3.289841960364e15_dp, 0.000000000017e15_dp, “Hz”): Rydberg constant times c in Hz
RYDBERG_CONSTANT_TIMES_HC_IN_EV_2010: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in eV”, 13.60569253_dp, 0.00000030_dp, “eV”): Rydberg constant times hc in eV
RYDBERG_CONSTANT_TIMES_HC_IN_J_2010: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in J”, 2.179872171e-18_dp, 0.000000096e-18_dp, “J”): Rydberg constant times hc in J
SACKUR_TETRODE_CONSTANT_1_K_100_KPA_2010: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 100 kPa)”, -1.1517078_dp, 0.0000023_dp, “”): Sackur-Tetrode constant (1 K, 100 kPa)
SACKUR_TETRODE_CONSTANT_1_K_101_325_KPA_2010: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 101.325 kPa)”, -1.1648708_dp, 0.0000023_dp, “”): Sackur-Tetrode constant (1 K, 101.325 kPa)
SECOND_RADIATION_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“second radiation constant”, 1.4387770e-2_dp, 0.0000013e-2_dp, “m K”): second radiation constant
SHIELDED_HELION_GYROMAG_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio”, 2.037894659e8_dp, 0.000000051e8_dp, “s^-1 T^-1”): shielded helion gyromag. ratio
SHIELDED_HELION_GYROMAG_RATIO_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio over 2 pi”, 32.43410084_dp, 0.00000081_dp, “MHz T^-1”): shielded helion gyromag. ratio over 2 pi
SHIELDED_HELION_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom.”, -1.074553044e-26_dp, 0.000000027e-26_dp, “J T^-1”): shielded helion mag. mom.
SHIELDED_HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to Bohr magneton ratio”, -1.158671471e-3_dp, 0.000000014e-3_dp, “”): shielded helion mag. mom. to Bohr magneton ratio
SHIELDED_HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to nuclear magneton ratio”, -2.127497718_dp, 0.000000025_dp, “”): shielded helion mag. mom. to nuclear magneton ratio
SHIELDED_HELION_TO_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to proton mag. mom. ratio”, -0.761766558_dp, 0.000000011_dp, “”): shielded helion to proton mag. mom. ratio
SHIELDED_HELION_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to shielded proton mag. mom. ratio”, -0.7617861313_dp, 0.0000000033_dp, “”): shielded helion to shielded proton mag. mom. ratio
SHIELDED_PROTON_GYROMAG_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio”, 2.675153268e8_dp, 0.000000066e8_dp, “s^-1 T^-1”): shielded proton gyromag. ratio
SHIELDED_PROTON_GYROMAG_RATIO_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio over 2 pi”, 42.5763866_dp, 0.0000010_dp, “MHz T^-1”): shielded proton gyromag. ratio over 2 pi
SHIELDED_PROTON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom.”, 1.410570499e-26_dp, 0.000000035e-26_dp, “J T^-1”): shielded proton mag. mom.
SHIELDED_PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to Bohr magneton ratio”, 1.520993128e-3_dp, 0.000000017e-3_dp, “”): shielded proton mag. mom. to Bohr magneton ratio
SHIELDED_PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to nuclear magneton ratio”, 2.792775598_dp, 0.000000030_dp, “”): shielded proton mag. mom. to nuclear magneton ratio
SPEED_OF_LIGHT_IN_VACUUM_2010: type(codata_constant_type), parameter = codata_constant_type(“speed of light in vacuum”, 299792458_dp, 0.0_dp, “m s^-1”): speed of light in vacuum
STANDARD_ACCELERATION_OF_GRAVITY_2010: type(codata_constant_type), parameter = codata_constant_type(“standard acceleration of gravity”, 9.80665_dp, 0.0_dp, “m s^-2”): standard acceleration of gravity
STANDARD_ATMOSPHERE_2010: type(codata_constant_type), parameter = codata_constant_type(“standard atmosphere”, 101325_dp, 0.0_dp, “Pa”): standard atmosphere
STANDARD_STATE_PRESSURE_2010: type(codata_constant_type), parameter = codata_constant_type(“standard-state pressure”, 100000_dp, 0.0_dp, “Pa”): standard-state pressure
STEFAN_BOLTZMANN_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Stefan-Boltzmann constant”, 5.670373e-8_dp, 0.000021e-8_dp, “W m^-2 K^-4”): Stefan-Boltzmann constant
TAU_COMPTON_WAVELENGTH_2010: type(codata_constant_type), parameter = codata_constant_type(“tau Compton wavelength”, 0.697787e-15_dp, 0.000063e-15_dp, “m”): tau Compton wavelength
TAU_COMPTON_WAVELENGTH_OVER_2_PI_2010: type(codata_constant_type), parameter = codata_constant_type(“tau Compton wavelength over 2 pi”, 0.111056e-15_dp, 0.000010e-15_dp, “m”): tau Compton wavelength over 2 pi
TAU_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“tau-electron mass ratio”, 3477.15_dp, 0.31_dp, “”): tau-electron mass ratio
TAU_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“tau mass”, 3.16747e-27_dp, 0.00029e-27_dp, “kg”): tau mass
TAU_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“tau mass energy equivalent”, 2.84678e-10_dp, 0.00026e-10_dp, “J”): tau mass energy equivalent
TAU_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“tau mass energy equivalent in MeV”, 1776.82_dp, 0.16_dp, “MeV”): tau mass energy equivalent in MeV
TAU_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“tau mass in u”, 1.90749_dp, 0.00017_dp, “u”): tau mass in u
TAU_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“tau molar mass”, 1.90749e-3_dp, 0.00017e-3_dp, “kg mol^-1”): tau molar mass
TAU_MUON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“tau-muon mass ratio”, 16.8167_dp, 0.0015_dp, “”): tau-muon mass ratio
TAU_NEUTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“tau-neutron mass ratio”, 1.89111_dp, 0.00017_dp, “”): tau-neutron mass ratio
TAU_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“tau-proton mass ratio”, 1.89372_dp, 0.00017_dp, “”): tau-proton mass ratio
THOMSON_CROSS_SECTION_2010: type(codata_constant_type), parameter = codata_constant_type(“Thomson cross section”, 0.6652458734e-28_dp, 0.0000000013e-28_dp, “m^2”): Thomson cross section
TRITON_ELECTRON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“triton-electron mass ratio”, 5496.9215267_dp, 0.0000050_dp, “”): triton-electron mass ratio
TRITON_G_FACTOR_2010: type(codata_constant_type), parameter = codata_constant_type(“triton g factor”, 5.957924896_dp, 0.000000076_dp, “”): triton g factor
TRITON_MAG_MOM_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom.”, 1.504609447e-26_dp, 0.000000038e-26_dp, “J T^-1”): triton mag. mom.
TRITON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to Bohr magneton ratio”, 1.622393657e-3_dp, 0.000000021e-3_dp, “”): triton mag. mom. to Bohr magneton ratio
TRITON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to nuclear magneton ratio”, 2.978962448_dp, 0.000000038_dp, “”): triton mag. mom. to nuclear magneton ratio
TRITON_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mass”, 5.00735630e-27_dp, 0.00000022e-27_dp, “kg”): triton mass
TRITON_MASS_ENERGY_EQUIVALENT_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent”, 4.50038741e-10_dp, 0.00000020e-10_dp, “J”): triton mass energy equivalent
TRITON_MASS_ENERGY_EQUIVALENT_IN_MEV_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent in MeV”, 2808.921005_dp, 0.000062_dp, “MeV”): triton mass energy equivalent in MeV
TRITON_MASS_IN_U_2010: type(codata_constant_type), parameter = codata_constant_type(“triton mass in u”, 3.0155007134_dp, 0.0000000025_dp, “u”): triton mass in u
TRITON_MOLAR_MASS_2010: type(codata_constant_type), parameter = codata_constant_type(“triton molar mass”, 3.0155007134e-3_dp, 0.0000000025e-3_dp, “kg mol^-1”): triton molar mass
TRITON_PROTON_MASS_RATIO_2010: type(codata_constant_type), parameter = codata_constant_type(“triton-proton mass ratio”, 2.9937170308_dp, 0.0000000025_dp, “”): triton-proton mass ratio
UNIFIED_ATOMIC_MASS_UNIT_2010: type(codata_constant_type), parameter = codata_constant_type(“unified atomic mass unit”, 1.660538921e-27_dp, 0.000000073e-27_dp, “kg”): unified atomic mass unit
VON_KLITZING_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“von Klitzing constant”, 25812.8074434_dp, 0.0000084_dp, “ohm”): von Klitzing constant
WEAK_MIXING_ANGLE_2010: type(codata_constant_type), parameter = codata_constant_type(“weak mixing angle”, 0.2223_dp, 0.0021_dp, “”): weak mixing angle
WIEN_FREQUENCY_DISPLACEMENT_LAW_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Wien frequency displacement law constant”, 5.8789254e10_dp, 0.0000053e10_dp, “Hz K^-1”): Wien frequency displacement law constant
WIEN_WAVELENGTH_DISPLACEMENT_LAW_CONSTANT_2010: type(codata_constant_type), parameter = codata_constant_type(“Wien wavelength displacement law constant”, 2.8977721e-3_dp, 0.0000026e-3_dp, “m K”): Wien wavelength displacement law constant

\(\)

module codata__constants_2014: Codata Constants - Autogenerated
\(\)

Parameters

YEAR_2014: integer(kind=int32), parameter = 2014: Year of release.
LATTICE_SPACING_OF_SILICON_2014: type(codata_constant_type), parameter = codata_constant_type(“{220} lattice spacing of silicon”, 192.0155714e-12_dp, 0.0000032e-12_dp, “m”): {220} lattice spacing of silicon
ALPHA_PARTICLE_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-electron mass ratio”, 7294.29954136_dp, 0.00000024_dp, “”): alpha particle-electron mass ratio
ALPHA_PARTICLE_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass”, 6.644657230e-27_dp, 0.000000082e-27_dp, “kg”): alpha particle mass
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent”, 5.971920097e-10_dp, 0.000000073e-10_dp, “J”): alpha particle mass energy equivalent
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent in MeV”, 3727.379378_dp, 0.000023_dp, “MeV”): alpha particle mass energy equivalent in MeV
ALPHA_PARTICLE_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass in u”, 4.001506179127_dp, 0.000000000063_dp, “u”): alpha particle mass in u
ALPHA_PARTICLE_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle molar mass”, 4.001506179127e-3_dp, 0.000000000063e-3_dp, “kg mol^-1”): alpha particle molar mass
ALPHA_PARTICLE_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-proton mass ratio”, 3.97259968907_dp, 0.00000000036_dp, “”): alpha particle-proton mass ratio
ANGSTROM_STAR_2014: type(codata_constant_type), parameter = codata_constant_type(“Angstrom star”, 1.00001495e-10_dp, 0.00000090e-10_dp, “m”): Angstrom star
ATOMIC_MASS_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant”, 1.660539040e-27_dp, 0.000000020e-27_dp, “kg”): atomic mass constant
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent”, 1.492418062e-10_dp, 0.000000018e-10_dp, “J”): atomic mass constant energy equivalent
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent in MeV”, 931.4940954_dp, 0.0000057_dp, “MeV”): atomic mass constant energy equivalent in MeV
ATOMIC_MASS_UNIT_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-electron volt relationship”, 931.4940954e6_dp, 0.0000057e6_dp, “eV”): atomic mass unit-electron volt relationship
ATOMIC_MASS_UNIT_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hartree relationship”, 3.4231776902e7_dp, 0.0000000016e7_dp, “E_h”): atomic mass unit-hartree relationship
ATOMIC_MASS_UNIT_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hertz relationship”, 2.2523427206e23_dp, 0.0000000010e23_dp, “Hz”): atomic mass unit-hertz relationship
ATOMIC_MASS_UNIT_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-inverse meter relationship”, 7.5130066166e14_dp, 0.0000000034e14_dp, “m^-1”): atomic mass unit-inverse meter relationship
ATOMIC_MASS_UNIT_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-joule relationship”, 1.492418062e-10_dp, 0.000000018e-10_dp, “J”): atomic mass unit-joule relationship
ATOMIC_MASS_UNIT_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kelvin relationship”, 1.08095438e13_dp, 0.00000062e13_dp, “K”): atomic mass unit-kelvin relationship
ATOMIC_MASS_UNIT_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kilogram relationship”, 1.660539040e-27_dp, 0.000000020e-27_dp, “kg”): atomic mass unit-kilogram relationship
ATOMIC_UNIT_OF_1ST_HYPERPOLARIZABILITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 1st hyperpolarizability”, 3.206361329e-53_dp, 0.000000020e-53_dp, “C^3 m^3 J^-2”): atomic unit of 1st hyperpolarizability
ATOMIC_UNIT_OF_2ND_HYPERPOLARIZABILITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 2nd hyperpolarizability”, 6.235380085e-65_dp, 0.000000077e-65_dp, “C^4 m^4 J^-3”): atomic unit of 2nd hyperpolarizability
ATOMIC_UNIT_OF_ACTION_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of action”, 1.054571800e-34_dp, 0.000000013e-34_dp, “J s”): atomic unit of action
ATOMIC_UNIT_OF_CHARGE_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge”, 1.6021766208e-19_dp, 0.0000000098e-19_dp, “C”): atomic unit of charge
ATOMIC_UNIT_OF_CHARGE_DENSITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge density”, 1.0812023770e12_dp, 0.0000000067e12_dp, “C m^-3”): atomic unit of charge density
ATOMIC_UNIT_OF_CURRENT_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of current”, 6.623618183e-3_dp, 0.000000041e-3_dp, “A”): atomic unit of current
ATOMIC_UNIT_OF_ELECTRIC_DIPOLE_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric dipole mom.”, 8.478353552e-30_dp, 0.000000052e-30_dp, “C m”): atomic unit of electric dipole mom.
ATOMIC_UNIT_OF_ELECTRIC_FIELD_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field”, 5.142206707e11_dp, 0.000000032e11_dp, “V m^-1”): atomic unit of electric field
ATOMIC_UNIT_OF_ELECTRIC_FIELD_GRADIENT_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field gradient”, 9.717362356e21_dp, 0.000000060e21_dp, “V m^-2”): atomic unit of electric field gradient
ATOMIC_UNIT_OF_ELECTRIC_POLARIZABILITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric polarizability”, 1.6487772731e-41_dp, 0.0000000011e-41_dp, “C^2 m^2 J^-1”): atomic unit of electric polarizability
ATOMIC_UNIT_OF_ELECTRIC_POTENTIAL_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric potential”, 27.21138602_dp, 0.00000017_dp, “V”): atomic unit of electric potential
ATOMIC_UNIT_OF_ELECTRIC_QUADRUPOLE_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric quadrupole mom.”, 4.486551484e-40_dp, 0.000000028e-40_dp, “C m^2”): atomic unit of electric quadrupole mom.
ATOMIC_UNIT_OF_ENERGY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of energy”, 4.359744650e-18_dp, 0.000000054e-18_dp, “J”): atomic unit of energy
ATOMIC_UNIT_OF_FORCE_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of force”, 8.23872336e-8_dp, 0.00000010e-8_dp, “N”): atomic unit of force
ATOMIC_UNIT_OF_LENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of length”, 0.52917721067e-10_dp, 0.00000000012e-10_dp, “m”): atomic unit of length
ATOMIC_UNIT_OF_MAG_DIPOLE_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. dipole mom.”, 1.854801999e-23_dp, 0.000000011e-23_dp, “J T^-1”): atomic unit of mag. dipole mom.
ATOMIC_UNIT_OF_MAG_FLUX_DENSITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. flux density”, 2.350517550e5_dp, 0.000000014e5_dp, “T”): atomic unit of mag. flux density
ATOMIC_UNIT_OF_MAGNETIZABILITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of magnetizability”, 7.8910365886e-29_dp, 0.0000000090e-29_dp, “J T^-2”): atomic unit of magnetizability
ATOMIC_UNIT_OF_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mass”, 9.10938356e-31_dp, 0.00000011e-31_dp, “kg”): atomic unit of mass
ATOMIC_UNIT_OF_MOMUM_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mom.um”, 1.992851882e-24_dp, 0.000000024e-24_dp, “kg m s^-1”): atomic unit of mom.um
ATOMIC_UNIT_OF_PERMITTIVITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of permittivity”, 1.112650056e-10_dp, 0.0_dp, “F m^-1”): atomic unit of permittivity
ATOMIC_UNIT_OF_TIME_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of time”, 2.418884326509e-17_dp, 0.000000000014e-17_dp, “s”): atomic unit of time
ATOMIC_UNIT_OF_VELOCITY_2014: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of velocity”, 2.18769126277e6_dp, 0.00000000050e6_dp, “m s^-1”): atomic unit of velocity
AVOGADRO_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Avogadro constant”, 6.022140857e23_dp, 0.000000074e23_dp, “mol^-1”): Avogadro constant
BOHR_MAGNETON_2014: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton”, 927.4009994e-26_dp, 0.0000057e-26_dp, “J T^-1”): Bohr magneton
BOHR_MAGNETON_IN_EV_T_2014: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in eV/T”, 5.7883818012e-5_dp, 0.0000000026e-5_dp, “eV T^-1”): Bohr magneton in eV/T
BOHR_MAGNETON_IN_HZ_T_2014: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in Hz/T”, 13.996245042e9_dp, 0.000000086e9_dp, “Hz T^-1”): Bohr magneton in Hz/T
BOHR_MAGNETON_IN_INVERSE_METERS_PER_TESLA_2014: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in inverse meters per tesla”, 46.68644814_dp, 0.00000029_dp, “m^-1 T^-1”): Bohr magneton in inverse meters per tesla
BOHR_MAGNETON_IN_K_T_2014: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in K/T”, 0.67171405_dp, 0.00000039_dp, “K T^-1”): Bohr magneton in K/T
BOHR_RADIUS_2014: type(codata_constant_type), parameter = codata_constant_type(“Bohr radius”, 0.52917721067e-10_dp, 0.00000000012e-10_dp, “m”): Bohr radius
BOLTZMANN_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant”, 1.38064852e-23_dp, 0.00000079e-23_dp, “J K^-1”): Boltzmann constant
BOLTZMANN_CONSTANT_IN_EV_K_2014: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in eV/K”, 8.6173303e-5_dp, 0.0000050e-5_dp, “eV K^-1”): Boltzmann constant in eV/K
BOLTZMANN_CONSTANT_IN_HZ_K_2014: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in Hz/K”, 2.0836612e10_dp, 0.0000012e10_dp, “Hz K^-1”): Boltzmann constant in Hz/K
BOLTZMANN_CONSTANT_IN_INVERSE_METERS_PER_KELVIN_2014: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in inverse meters per kelvin”, 69.503457_dp, 0.000040_dp, “m^-1 K^-1”): Boltzmann constant in inverse meters per kelvin
CHARACTERISTIC_IMPEDANCE_OF_VACUUM_2014: type(codata_constant_type), parameter = codata_constant_type(“characteristic impedance of vacuum”, 376.730313461_dp, 0.0_dp, “ohm”): characteristic impedance of vacuum
CLASSICAL_ELECTRON_RADIUS_2014: type(codata_constant_type), parameter = codata_constant_type(“classical electron radius”, 2.8179403227e-15_dp, 0.0000000019e-15_dp, “m”): classical electron radius
COMPTON_WAVELENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“Compton wavelength”, 2.4263102367e-12_dp, 0.0000000011e-12_dp, “m”): Compton wavelength
COMPTON_WAVELENGTH_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“Compton wavelength over 2 pi”, 386.15926764e-15_dp, 0.00000018e-15_dp, “m”): Compton wavelength over 2 pi
CONDUCTANCE_QUANTUM_2014: type(codata_constant_type), parameter = codata_constant_type(“conductance quantum”, 7.7480917310e-5_dp, 0.0000000018e-5_dp, “S”): conductance quantum
CONVENTIONAL_VALUE_OF_JOSEPHSON_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“conventional value of Josephson constant”, 483597.9e9_dp, 0.0_dp, “Hz V^-1”): conventional value of Josephson constant
CONVENTIONAL_VALUE_OF_VON_KLITZING_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“conventional value of von Klitzing constant”, 25812.807_dp, 0.0_dp, “ohm”): conventional value of von Klitzing constant
CU_X_UNIT_2014: type(codata_constant_type), parameter = codata_constant_type(“Cu x unit”, 1.00207697e-13_dp, 0.00000028e-13_dp, “m”): Cu x unit
DEUTERON_ELECTRON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mag. mom. ratio”, -4.664345535e-4_dp, 0.000000026e-4_dp, “”): deuteron-electron mag. mom. ratio
DEUTERON_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mass ratio”, 3670.48296785_dp, 0.00000013_dp, “”): deuteron-electron mass ratio
DEUTERON_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron g factor”, 0.8574382311_dp, 0.0000000048_dp, “”): deuteron g factor
DEUTERON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom.”, 0.4330735040e-26_dp, 0.0000000036e-26_dp, “J T^-1”): deuteron mag. mom.
DEUTERON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to Bohr magneton ratio”, 0.4669754554e-3_dp, 0.0000000026e-3_dp, “”): deuteron mag. mom. to Bohr magneton ratio
DEUTERON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to nuclear magneton ratio”, 0.8574382311_dp, 0.0000000048_dp, “”): deuteron mag. mom. to nuclear magneton ratio
DEUTERON_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass”, 3.343583719e-27_dp, 0.000000041e-27_dp, “kg”): deuteron mass
DEUTERON_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent”, 3.005063183e-10_dp, 0.000000037e-10_dp, “J”): deuteron mass energy equivalent
DEUTERON_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent in MeV”, 1875.612928_dp, 0.000012_dp, “MeV”): deuteron mass energy equivalent in MeV
DEUTERON_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass in u”, 2.013553212745_dp, 0.000000000040_dp, “u”): deuteron mass in u
DEUTERON_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron molar mass”, 2.013553212745e-3_dp, 0.000000000040e-3_dp, “kg mol^-1”): deuteron molar mass
DEUTERON_NEUTRON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron-neutron mag. mom. ratio”, -0.44820652_dp, 0.00000011_dp, “”): deuteron-neutron mag. mom. ratio
DEUTERON_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mag. mom. ratio”, 0.3070122077_dp, 0.0000000015_dp, “”): deuteron-proton mag. mom. ratio
DEUTERON_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mass ratio”, 1.99900750087_dp, 0.00000000019_dp, “”): deuteron-proton mass ratio
DEUTERON_RMS_CHARGE_RADIUS_2014: type(codata_constant_type), parameter = codata_constant_type(“deuteron rms charge radius”, 2.1413e-15_dp, 0.0025e-15_dp, “m”): deuteron rms charge radius
ELECTRIC_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“electric constant”, 8.854187817e-12_dp, 0.0_dp, “F m^-1”): electric constant
ELECTRON_CHARGE_TO_MASS_QUOTIENT_2014: type(codata_constant_type), parameter = codata_constant_type(“electron charge to mass quotient”, -1.758820024e11_dp, 0.000000011e11_dp, “C kg^-1”): electron charge to mass quotient
ELECTRON_DEUTERON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mag. mom. ratio”, -2143.923499_dp, 0.000012_dp, “”): electron-deuteron mag. mom. ratio
ELECTRON_DEUTERON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mass ratio”, 2.724437107484e-4_dp, 0.000000000096e-4_dp, “”): electron-deuteron mass ratio
ELECTRON_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“electron g factor”, -2.00231930436182_dp, 0.00000000000052_dp, “”): electron g factor
ELECTRON_GYROMAG_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio”, 1.760859644e11_dp, 0.000000011e11_dp, “s^-1 T^-1”): electron gyromag. ratio
ELECTRON_GYROMAG_RATIO_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio over 2 pi”, 28024.95164_dp, 0.00017_dp, “MHz T^-1”): electron gyromag. ratio over 2 pi
ELECTRON_HELION_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-helion mass ratio”, 1.819543074854e-4_dp, 0.000000000088e-4_dp, “”): electron-helion mass ratio
ELECTRON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom.”, -928.4764620e-26_dp, 0.0000057e-26_dp, “J T^-1”): electron mag. mom.
ELECTRON_MAG_MOM_ANOMALY_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. anomaly”, 1.15965218091e-3_dp, 0.00000000026e-3_dp, “”): electron mag. mom. anomaly
ELECTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to Bohr magneton ratio”, -1.00115965218091_dp, 0.00000000000026_dp, “”): electron mag. mom. to Bohr magneton ratio
ELECTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to nuclear magneton ratio”, -1838.28197234_dp, 0.00000017_dp, “”): electron mag. mom. to nuclear magneton ratio
ELECTRON_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mass”, 9.10938356e-31_dp, 0.00000011e-31_dp, “kg”): electron mass
ELECTRON_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent”, 8.18710565e-14_dp, 0.00000010e-14_dp, “J”): electron mass energy equivalent
ELECTRON_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent in MeV”, 0.5109989461_dp, 0.0000000031_dp, “MeV”): electron mass energy equivalent in MeV
ELECTRON_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“electron mass in u”, 5.48579909070e-4_dp, 0.00000000016e-4_dp, “u”): electron mass in u
ELECTRON_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“electron molar mass”, 5.48579909070e-7_dp, 0.00000000016e-7_dp, “kg mol^-1”): electron molar mass
ELECTRON_MUON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mag. mom. ratio”, 206.7669880_dp, 0.0000046_dp, “”): electron-muon mag. mom. ratio
ELECTRON_MUON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mass ratio”, 4.83633170e-3_dp, 0.00000011e-3_dp, “”): electron-muon mass ratio
ELECTRON_NEUTRON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mag. mom. ratio”, 960.92050_dp, 0.00023_dp, “”): electron-neutron mag. mom. ratio
ELECTRON_NEUTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mass ratio”, 5.4386734428e-4_dp, 0.0000000027e-4_dp, “”): electron-neutron mass ratio
ELECTRON_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mag. mom. ratio”, -658.2106866_dp, 0.0000020_dp, “”): electron-proton mag. mom. ratio
ELECTRON_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mass ratio”, 5.44617021352e-4_dp, 0.00000000052e-4_dp, “”): electron-proton mass ratio
ELECTRON_TAU_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-tau mass ratio”, 2.87592e-4_dp, 0.00026e-4_dp, “”): electron-tau mass ratio
ELECTRON_TO_ALPHA_PARTICLE_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron to alpha particle mass ratio”, 1.370933554798e-4_dp, 0.000000000045e-4_dp, “”): electron to alpha particle mass ratio
ELECTRON_TO_SHIELDED_HELION_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded helion mag. mom. ratio”, 864.058257_dp, 0.000010_dp, “”): electron to shielded helion mag. mom. ratio
ELECTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded proton mag. mom. ratio”, -658.2275971_dp, 0.0000072_dp, “”): electron to shielded proton mag. mom. ratio
ELECTRON_TRITON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“electron-triton mass ratio”, 1.819200062203e-4_dp, 0.000000000084e-4_dp, “”): electron-triton mass ratio
ELECTRON_VOLT_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt”, 1.6021766208e-19_dp, 0.0000000098e-19_dp, “J”): electron volt
ELECTRON_VOLT_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-atomic mass unit relationship”, 1.0735441105e-9_dp, 0.0000000066e-9_dp, “u”): electron volt-atomic mass unit relationship
ELECTRON_VOLT_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hartree relationship”, 3.674932248e-2_dp, 0.000000023e-2_dp, “E_h”): electron volt-hartree relationship
ELECTRON_VOLT_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hertz relationship”, 2.417989262e14_dp, 0.000000015e14_dp, “Hz”): electron volt-hertz relationship
ELECTRON_VOLT_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-inverse meter relationship”, 8.065544005e5_dp, 0.000000050e5_dp, “m^-1”): electron volt-inverse meter relationship
ELECTRON_VOLT_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-joule relationship”, 1.6021766208e-19_dp, 0.0000000098e-19_dp, “J”): electron volt-joule relationship
ELECTRON_VOLT_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kelvin relationship”, 1.16045221e4_dp, 0.00000067e4_dp, “K”): electron volt-kelvin relationship
ELECTRON_VOLT_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kilogram relationship”, 1.782661907e-36_dp, 0.000000011e-36_dp, “kg”): electron volt-kilogram relationship
ELEMENTARY_CHARGE_2014: type(codata_constant_type), parameter = codata_constant_type(“elementary charge”, 1.6021766208e-19_dp, 0.0000000098e-19_dp, “C”): elementary charge
ELEMENTARY_CHARGE_OVER_H_2014: type(codata_constant_type), parameter = codata_constant_type(“elementary charge over h”, 2.417989262e14_dp, 0.000000015e14_dp, “A J^-1”): elementary charge over h
FARADAY_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Faraday constant”, 96485.33289_dp, 0.00059_dp, “C mol^-1”): Faraday constant
FARADAY_CONSTANT_FOR_CONVENTIONAL_ELECTRIC_CURRENT_2014: type(codata_constant_type), parameter = codata_constant_type(“Faraday constant for conventional electric current”, 96485.3251_dp, 0.0012_dp, “C_90 mol^-1”): Faraday constant for conventional electric current
FERMI_COUPLING_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Fermi coupling constant”, 1.1663787e-5_dp, 0.0000006e-5_dp, “GeV^-2”): Fermi coupling constant
FINE_STRUCTURE_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“fine-structure constant”, 7.2973525664e-3_dp, 0.0000000017e-3_dp, “”): fine-structure constant
FIRST_RADIATION_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant”, 3.741771790e-16_dp, 0.000000046e-16_dp, “W m^2”): first radiation constant
FIRST_RADIATION_CONSTANT_FOR_SPECTRAL_RADIANCE_2014: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant for spectral radiance”, 1.191042953e-16_dp, 0.000000015e-16_dp, “W m^2 sr^-1”): first radiation constant for spectral radiance
HARTREE_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-atomic mass unit relationship”, 2.9212623197e-8_dp, 0.0000000013e-8_dp, “u”): hartree-atomic mass unit relationship
HARTREE_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-electron volt relationship”, 27.21138602_dp, 0.00000017_dp, “eV”): hartree-electron volt relationship
HARTREE_ENERGY_2014: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy”, 4.359744650e-18_dp, 0.000000054e-18_dp, “J”): Hartree energy
HARTREE_ENERGY_IN_EV_2014: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy in eV”, 27.21138602_dp, 0.00000017_dp, “eV”): Hartree energy in eV
HARTREE_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-hertz relationship”, 6.579683920711e15_dp, 0.000000000039e15_dp, “Hz”): hartree-hertz relationship
HARTREE_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-inverse meter relationship”, 2.194746313702e7_dp, 0.000000000013e7_dp, “m^-1”): hartree-inverse meter relationship
HARTREE_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-joule relationship”, 4.359744650e-18_dp, 0.000000054e-18_dp, “J”): hartree-joule relationship
HARTREE_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-kelvin relationship”, 3.1577513e5_dp, 0.0000018e5_dp, “K”): hartree-kelvin relationship
HARTREE_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hartree-kilogram relationship”, 4.850870129e-35_dp, 0.000000060e-35_dp, “kg”): hartree-kilogram relationship
HELION_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“helion-electron mass ratio”, 5495.88527922_dp, 0.00000027_dp, “”): helion-electron mass ratio
HELION_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“helion g factor”, -4.255250616_dp, 0.000000050_dp, “”): helion g factor
HELION_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom.”, -1.074617522e-26_dp, 0.000000014e-26_dp, “J T^-1”): helion mag. mom.
HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to Bohr magneton ratio”, -1.158740958e-3_dp, 0.000000014e-3_dp, “”): helion mag. mom. to Bohr magneton ratio
HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to nuclear magneton ratio”, -2.127625308_dp, 0.000000025_dp, “”): helion mag. mom. to nuclear magneton ratio
HELION_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mass”, 5.006412700e-27_dp, 0.000000062e-27_dp, “kg”): helion mass
HELION_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent”, 4.499539341e-10_dp, 0.000000055e-10_dp, “J”): helion mass energy equivalent
HELION_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent in MeV”, 2808.391586_dp, 0.000017_dp, “MeV”): helion mass energy equivalent in MeV
HELION_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“helion mass in u”, 3.01493224673_dp, 0.00000000012_dp, “u”): helion mass in u
HELION_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“helion molar mass”, 3.01493224673e-3_dp, 0.00000000012e-3_dp, “kg mol^-1”): helion molar mass
HELION_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“helion-proton mass ratio”, 2.99315267046_dp, 0.00000000029_dp, “”): helion-proton mass ratio
HERTZ_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-atomic mass unit relationship”, 4.4398216616e-24_dp, 0.0000000020e-24_dp, “u”): hertz-atomic mass unit relationship
HERTZ_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-electron volt relationship”, 4.135667662e-15_dp, 0.000000025e-15_dp, “eV”): hertz-electron volt relationship
HERTZ_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-hartree relationship”, 1.5198298460088e-16_dp, 0.0000000000090e-16_dp, “E_h”): hertz-hartree relationship
HERTZ_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-inverse meter relationship”, 3.335640951e-9_dp, 0.0_dp, “m^-1”): hertz-inverse meter relationship
HERTZ_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-joule relationship”, 6.626070040e-34_dp, 0.000000081e-34_dp, “J”): hertz-joule relationship
HERTZ_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-kelvin relationship”, 4.7992447e-11_dp, 0.0000028e-11_dp, “K”): hertz-kelvin relationship
HERTZ_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“hertz-kilogram relationship”, 7.372497201e-51_dp, 0.000000091e-51_dp, “kg”): hertz-kilogram relationship
INVERSE_FINE_STRUCTURE_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse fine-structure constant”, 137.035999139_dp, 0.000000031_dp, “”): inverse fine-structure constant
INVERSE_METER_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-atomic mass unit relationship”, 1.33102504900e-15_dp, 0.00000000061e-15_dp, “u”): inverse meter-atomic mass unit relationship
INVERSE_METER_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-electron volt relationship”, 1.2398419739e-6_dp, 0.0000000076e-6_dp, “eV”): inverse meter-electron volt relationship
INVERSE_METER_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hartree relationship”, 4.556335252767e-8_dp, 0.000000000027e-8_dp, “E_h”): inverse meter-hartree relationship
INVERSE_METER_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hertz relationship”, 299792458_dp, 0.0_dp, “Hz”): inverse meter-hertz relationship
INVERSE_METER_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-joule relationship”, 1.986445824e-25_dp, 0.000000024e-25_dp, “J”): inverse meter-joule relationship
INVERSE_METER_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kelvin relationship”, 1.43877736e-2_dp, 0.00000083e-2_dp, “K”): inverse meter-kelvin relationship
INVERSE_METER_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kilogram relationship”, 2.210219057e-42_dp, 0.000000027e-42_dp, “kg”): inverse meter-kilogram relationship
INVERSE_OF_CONDUCTANCE_QUANTUM_2014: type(codata_constant_type), parameter = codata_constant_type(“inverse of conductance quantum”, 12906.4037278_dp, 0.0000029_dp, “ohm”): inverse of conductance quantum
JOSEPHSON_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Josephson constant”, 483597.8525e9_dp, 0.0030e9_dp, “Hz V^-1”): Josephson constant
JOULE_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-atomic mass unit relationship”, 6.700535363e9_dp, 0.000000082e9_dp, “u”): joule-atomic mass unit relationship
JOULE_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-electron volt relationship”, 6.241509126e18_dp, 0.000000038e18_dp, “eV”): joule-electron volt relationship
JOULE_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-hartree relationship”, 2.293712317e17_dp, 0.000000028e17_dp, “E_h”): joule-hartree relationship
JOULE_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-hertz relationship”, 1.509190205e33_dp, 0.000000019e33_dp, “Hz”): joule-hertz relationship
JOULE_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-inverse meter relationship”, 5.034116651e24_dp, 0.000000062e24_dp, “m^-1”): joule-inverse meter relationship
JOULE_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-kelvin relationship”, 7.2429731e22_dp, 0.0000042e22_dp, “K”): joule-kelvin relationship
JOULE_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“joule-kilogram relationship”, 1.112650056e-17_dp, 0.0_dp, “kg”): joule-kilogram relationship
KELVIN_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-atomic mass unit relationship”, 9.2510842e-14_dp, 0.0000053e-14_dp, “u”): kelvin-atomic mass unit relationship
KELVIN_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-electron volt relationship”, 8.6173303e-5_dp, 0.0000050e-5_dp, “eV”): kelvin-electron volt relationship
KELVIN_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hartree relationship”, 3.1668105e-6_dp, 0.0000018e-6_dp, “E_h”): kelvin-hartree relationship
KELVIN_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hertz relationship”, 2.0836612e10_dp, 0.0000012e10_dp, “Hz”): kelvin-hertz relationship
KELVIN_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-inverse meter relationship”, 69.503457_dp, 0.000040_dp, “m^-1”): kelvin-inverse meter relationship
KELVIN_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-joule relationship”, 1.38064852e-23_dp, 0.00000079e-23_dp, “J”): kelvin-joule relationship
KELVIN_KILOGRAM_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kelvin-kilogram relationship”, 1.53617865e-40_dp, 0.00000088e-40_dp, “kg”): kelvin-kilogram relationship
KILOGRAM_ATOMIC_MASS_UNIT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-atomic mass unit relationship”, 6.022140857e26_dp, 0.000000074e26_dp, “u”): kilogram-atomic mass unit relationship
KILOGRAM_ELECTRON_VOLT_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-electron volt relationship”, 5.609588650e35_dp, 0.000000034e35_dp, “eV”): kilogram-electron volt relationship
KILOGRAM_HARTREE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hartree relationship”, 2.061485823e34_dp, 0.000000025e34_dp, “E_h”): kilogram-hartree relationship
KILOGRAM_HERTZ_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hertz relationship”, 1.356392512e50_dp, 0.000000017e50_dp, “Hz”): kilogram-hertz relationship
KILOGRAM_INVERSE_METER_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-inverse meter relationship”, 4.524438411e41_dp, 0.000000056e41_dp, “m^-1”): kilogram-inverse meter relationship
KILOGRAM_JOULE_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-joule relationship”, 8.987551787e16_dp, 0.0_dp, “J”): kilogram-joule relationship
KILOGRAM_KELVIN_RELATIONSHIP_2014: type(codata_constant_type), parameter = codata_constant_type(“kilogram-kelvin relationship”, 6.5096595e39_dp, 0.0000037e39_dp, “K”): kilogram-kelvin relationship
LATTICE_PARAMETER_OF_SILICON_2014: type(codata_constant_type), parameter = codata_constant_type(“lattice parameter of silicon”, 543.1020504e-12_dp, 0.0000089e-12_dp, “m”): lattice parameter of silicon
LOSCHMIDT_CONSTANT_273_15_K_100_KPA_2014: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 100 kPa)”, 2.6516467e25_dp, 0.0000015e25_dp, “m^-3”): Loschmidt constant (273.15 K, 100 kPa)
LOSCHMIDT_CONSTANT_273_15_K_101_325_KPA_2014: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 101.325 kPa)”, 2.6867811e25_dp, 0.0000015e25_dp, “m^-3”): Loschmidt constant (273.15 K, 101.325 kPa)
MAG_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“mag. constant”, 12.566370614e-7_dp, 0.0_dp, “N A^-2”): mag. constant
MAG_FLUX_QUANTUM_2014: type(codata_constant_type), parameter = codata_constant_type(“mag. flux quantum”, 2.067833831e-15_dp, 0.000000013e-15_dp, “Wb”): mag. flux quantum
MOLAR_GAS_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“molar gas constant”, 8.3144598_dp, 0.0000048_dp, “J mol^-1 K^-1”): molar gas constant
MOLAR_MASS_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“molar mass constant”, 1e-3_dp, 0.0_dp, “kg mol^-1”): molar mass constant
MOLAR_MASS_OF_CARBON_12_2014: type(codata_constant_type), parameter = codata_constant_type(“molar mass of carbon-12”, 12e-3_dp, 0.0_dp, “kg mol^-1”): molar mass of carbon-12
MOLAR_PLANCK_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“molar Planck constant”, 3.9903127110e-10_dp, 0.0000000018e-10_dp, “J s mol^-1”): molar Planck constant
MOLAR_PLANCK_CONSTANT_TIMES_C_2014: type(codata_constant_type), parameter = codata_constant_type(“molar Planck constant times c”, 0.119626565582_dp, 0.000000000054_dp, “J m mol^-1”): molar Planck constant times c
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_100_KPA_2014: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 100 kPa)”, 22.710947e-3_dp, 0.000013e-3_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 100 kPa)
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_101_325_KPA_2014: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 101.325 kPa)”, 22.413962e-3_dp, 0.000013e-3_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 101.325 kPa)
MOLAR_VOLUME_OF_SILICON_2014: type(codata_constant_type), parameter = codata_constant_type(“molar volume of silicon”, 12.05883214e-6_dp, 0.00000061e-6_dp, “m^3 mol^-1”): molar volume of silicon
MO_X_UNIT_2014: type(codata_constant_type), parameter = codata_constant_type(“Mo x unit”, 1.00209952e-13_dp, 0.00000053e-13_dp, “m”): Mo x unit
MUON_COMPTON_WAVELENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“muon Compton wavelength”, 11.73444111e-15_dp, 0.00000026e-15_dp, “m”): muon Compton wavelength
MUON_COMPTON_WAVELENGTH_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“muon Compton wavelength over 2 pi”, 1.867594308e-15_dp, 0.000000042e-15_dp, “m”): muon Compton wavelength over 2 pi
MUON_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon-electron mass ratio”, 206.7682826_dp, 0.0000046_dp, “”): muon-electron mass ratio
MUON_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“muon g factor”, -2.0023318418_dp, 0.0000000013_dp, “”): muon g factor
MUON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom.”, -4.49044826e-26_dp, 0.00000010e-26_dp, “J T^-1”): muon mag. mom.
MUON_MAG_MOM_ANOMALY_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. anomaly”, 1.16592089e-3_dp, 0.00000063e-3_dp, “”): muon mag. mom. anomaly
MUON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to Bohr magneton ratio”, -4.84197048e-3_dp, 0.00000011e-3_dp, “”): muon mag. mom. to Bohr magneton ratio
MUON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to nuclear magneton ratio”, -8.89059705_dp, 0.00000020_dp, “”): muon mag. mom. to nuclear magneton ratio
MUON_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mass”, 1.883531594e-28_dp, 0.000000048e-28_dp, “kg”): muon mass
MUON_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent”, 1.692833774e-11_dp, 0.000000043e-11_dp, “J”): muon mass energy equivalent
MUON_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent in MeV”, 105.6583745_dp, 0.0000024_dp, “MeV”): muon mass energy equivalent in MeV
MUON_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“muon mass in u”, 0.1134289257_dp, 0.0000000025_dp, “u”): muon mass in u
MUON_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“muon molar mass”, 0.1134289257e-3_dp, 0.0000000025e-3_dp, “kg mol^-1”): muon molar mass
MUON_NEUTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon-neutron mass ratio”, 0.1124545167_dp, 0.0000000025_dp, “”): muon-neutron mass ratio
MUON_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mag. mom. ratio”, -3.183345142_dp, 0.000000071_dp, “”): muon-proton mag. mom. ratio
MUON_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mass ratio”, 0.1126095262_dp, 0.0000000025_dp, “”): muon-proton mass ratio
MUON_TAU_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“muon-tau mass ratio”, 5.94649e-2_dp, 0.00054e-2_dp, “”): muon-tau mass ratio
NATURAL_UNIT_OF_ACTION_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action”, 1.054571800e-34_dp, 0.000000013e-34_dp, “J s”): natural unit of action
NATURAL_UNIT_OF_ACTION_IN_EV_S_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action in eV s”, 6.582119514e-16_dp, 0.000000040e-16_dp, “eV s”): natural unit of action in eV s
NATURAL_UNIT_OF_ENERGY_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy”, 8.18710565e-14_dp, 0.00000010e-14_dp, “J”): natural unit of energy
NATURAL_UNIT_OF_ENERGY_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy in MeV”, 0.5109989461_dp, 0.0000000031_dp, “MeV”): natural unit of energy in MeV
NATURAL_UNIT_OF_LENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of length”, 386.15926764e-15_dp, 0.00000018e-15_dp, “m”): natural unit of length
NATURAL_UNIT_OF_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mass”, 9.10938356e-31_dp, 0.00000011e-31_dp, “kg”): natural unit of mass
NATURAL_UNIT_OF_MOMUM_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mom.um”, 2.730924488e-22_dp, 0.000000034e-22_dp, “kg m s^-1”): natural unit of mom.um
NATURAL_UNIT_OF_MOMUM_IN_MEV_C_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mom.um in MeV/c”, 0.5109989461_dp, 0.0000000031_dp, “MeV/c”): natural unit of mom.um in MeV/c
NATURAL_UNIT_OF_TIME_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of time”, 1.28808866712e-21_dp, 0.00000000058e-21_dp, “s”): natural unit of time
NATURAL_UNIT_OF_VELOCITY_2014: type(codata_constant_type), parameter = codata_constant_type(“natural unit of velocity”, 299792458_dp, 0.0_dp, “m s^-1”): natural unit of velocity
NEUTRON_COMPTON_WAVELENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron Compton wavelength”, 1.31959090481e-15_dp, 0.00000000088e-15_dp, “m”): neutron Compton wavelength
NEUTRON_COMPTON_WAVELENGTH_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron Compton wavelength over 2 pi”, 0.21001941536e-15_dp, 0.00000000014e-15_dp, “m”): neutron Compton wavelength over 2 pi
NEUTRON_ELECTRON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mag. mom. ratio”, 1.04066882e-3_dp, 0.00000025e-3_dp, “”): neutron-electron mag. mom. ratio
NEUTRON_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mass ratio”, 1838.68366158_dp, 0.00000090_dp, “”): neutron-electron mass ratio
NEUTRON_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron g factor”, -3.82608545_dp, 0.00000090_dp, “”): neutron g factor
NEUTRON_GYROMAG_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio”, 1.83247172e8_dp, 0.00000043e8_dp, “s^-1 T^-1”): neutron gyromag. ratio
NEUTRON_GYROMAG_RATIO_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio over 2 pi”, 29.1646933_dp, 0.0000069_dp, “MHz T^-1”): neutron gyromag. ratio over 2 pi
NEUTRON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom.”, -0.96623650e-26_dp, 0.00000023e-26_dp, “J T^-1”): neutron mag. mom.
NEUTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to Bohr magneton ratio”, -1.04187563e-3_dp, 0.00000025e-3_dp, “”): neutron mag. mom. to Bohr magneton ratio
NEUTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to nuclear magneton ratio”, -1.91304273_dp, 0.00000045_dp, “”): neutron mag. mom. to nuclear magneton ratio
NEUTRON_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mass”, 1.674927471e-27_dp, 0.000000021e-27_dp, “kg”): neutron mass
NEUTRON_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent”, 1.505349739e-10_dp, 0.000000019e-10_dp, “J”): neutron mass energy equivalent
NEUTRON_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent in MeV”, 939.5654133_dp, 0.0000058_dp, “MeV”): neutron mass energy equivalent in MeV
NEUTRON_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron mass in u”, 1.00866491588_dp, 0.00000000049_dp, “u”): neutron mass in u
NEUTRON_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron molar mass”, 1.00866491588e-3_dp, 0.00000000049e-3_dp, “kg mol^-1”): neutron molar mass
NEUTRON_MUON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-muon mass ratio”, 8.89248408_dp, 0.00000020_dp, “”): neutron-muon mass ratio
NEUTRON_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mag. mom. ratio”, -0.68497934_dp, 0.00000016_dp, “”): neutron-proton mag. mom. ratio
NEUTRON_PROTON_MASS_DIFFERENCE_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference”, 2.30557377e-30_dp, 0.00000085e-30_dp, “”): neutron-proton mass difference
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent”, 2.07214637e-13_dp, 0.00000076e-13_dp, “”): neutron-proton mass difference energy equivalent
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent in MeV”, 1.29333205_dp, 0.00000048_dp, “”): neutron-proton mass difference energy equivalent in MeV
NEUTRON_PROTON_MASS_DIFFERENCE_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference in u”, 0.00138844900_dp, 0.00000000051_dp, “”): neutron-proton mass difference in u
NEUTRON_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass ratio”, 1.00137841898_dp, 0.00000000051_dp, “”): neutron-proton mass ratio
NEUTRON_TAU_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron-tau mass ratio”, 0.528790_dp, 0.000048_dp, “”): neutron-tau mass ratio
NEUTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“neutron to shielded proton mag. mom. ratio”, -0.68499694_dp, 0.00000016_dp, “”): neutron to shielded proton mag. mom. ratio
NEWTONIAN_CONSTANT_OF_GRAVITATION_2014: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation”, 6.67408e-11_dp, 0.00031e-11_dp, “m^3 kg^-1 s^-2”): Newtonian constant of gravitation
NEWTONIAN_CONSTANT_OF_GRAVITATION_OVER_H_BAR_C_2014: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation over h-bar c”, 6.70861e-39_dp, 0.00031e-39_dp, “(GeV/c^2)^-2”): Newtonian constant of gravitation over h-bar c
NUCLEAR_MAGNETON_2014: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton”, 5.050783699e-27_dp, 0.000000031e-27_dp, “J T^-1”): nuclear magneton
NUCLEAR_MAGNETON_IN_EV_T_2014: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in eV/T”, 3.1524512550e-8_dp, 0.0000000015e-8_dp, “eV T^-1”): nuclear magneton in eV/T
NUCLEAR_MAGNETON_IN_INVERSE_METERS_PER_TESLA_2014: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in inverse meters per tesla”, 2.542623432e-2_dp, 0.000000016e-2_dp, “m^-1 T^-1”): nuclear magneton in inverse meters per tesla
NUCLEAR_MAGNETON_IN_K_T_2014: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in K/T”, 3.6582690e-4_dp, 0.0000021e-4_dp, “K T^-1”): nuclear magneton in K/T
NUCLEAR_MAGNETON_IN_MHZ_T_2014: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in MHz/T”, 7.622593285_dp, 0.000000047_dp, “MHz T^-1”): nuclear magneton in MHz/T
PLANCK_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck constant”, 6.626070040e-34_dp, 0.000000081e-34_dp, “J s”): Planck constant
PLANCK_CONSTANT_IN_EV_S_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck constant in eV s”, 4.135667662e-15_dp, 0.000000025e-15_dp, “eV s”): Planck constant in eV s
PLANCK_CONSTANT_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck constant over 2 pi”, 1.054571800e-34_dp, 0.000000013e-34_dp, “J s”): Planck constant over 2 pi
PLANCK_CONSTANT_OVER_2_PI_IN_EV_S_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck constant over 2 pi in eV s”, 6.582119514e-16_dp, 0.000000040e-16_dp, “eV s”): Planck constant over 2 pi in eV s
PLANCK_CONSTANT_OVER_2_PI_TIMES_C_IN_MEV_FM_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck constant over 2 pi times c in MeV fm”, 197.3269788_dp, 0.0000012_dp, “MeV fm”): Planck constant over 2 pi times c in MeV fm
PLANCK_LENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck length”, 1.616229e-35_dp, 0.000038e-35_dp, “m”): Planck length
PLANCK_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck mass”, 2.176470e-8_dp, 0.000051e-8_dp, “kg”): Planck mass
PLANCK_MASS_ENERGY_EQUIVALENT_IN_GEV_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck mass energy equivalent in GeV”, 1.220910e19_dp, 0.000029e19_dp, “GeV”): Planck mass energy equivalent in GeV
PLANCK_TEMPERATURE_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck temperature”, 1.416808e32_dp, 0.000033e32_dp, “K”): Planck temperature
PLANCK_TIME_2014: type(codata_constant_type), parameter = codata_constant_type(“Planck time”, 5.39116e-44_dp, 0.00013e-44_dp, “s”): Planck time
PROTON_CHARGE_TO_MASS_QUOTIENT_2014: type(codata_constant_type), parameter = codata_constant_type(“proton charge to mass quotient”, 9.578833226e7_dp, 0.000000059e7_dp, “C kg^-1”): proton charge to mass quotient
PROTON_COMPTON_WAVELENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“proton Compton wavelength”, 1.32140985396e-15_dp, 0.00000000061e-15_dp, “m”): proton Compton wavelength
PROTON_COMPTON_WAVELENGTH_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“proton Compton wavelength over 2 pi”, 0.210308910109e-15_dp, 0.000000000097e-15_dp, “m”): proton Compton wavelength over 2 pi
PROTON_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton-electron mass ratio”, 1836.15267389_dp, 0.00000017_dp, “”): proton-electron mass ratio
PROTON_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“proton g factor”, 5.585694702_dp, 0.000000017_dp, “”): proton g factor
PROTON_GYROMAG_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio”, 2.675221900e8_dp, 0.000000018e8_dp, “s^-1 T^-1”): proton gyromag. ratio
PROTON_GYROMAG_RATIO_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio over 2 pi”, 42.57747892_dp, 0.00000029_dp, “MHz T^-1”): proton gyromag. ratio over 2 pi
PROTON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom.”, 1.4106067873e-26_dp, 0.0000000097e-26_dp, “J T^-1”): proton mag. mom.
PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to Bohr magneton ratio”, 1.5210322053e-3_dp, 0.0000000046e-3_dp, “”): proton mag. mom. to Bohr magneton ratio
PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to nuclear magneton ratio”, 2.7928473508_dp, 0.0000000085_dp, “”): proton mag. mom. to nuclear magneton ratio
PROTON_MAG_SHIELDING_CORRECTION_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mag. shielding correction”, 25.691e-6_dp, 0.011e-6_dp, “”): proton mag. shielding correction
PROTON_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mass”, 1.672621898e-27_dp, 0.000000021e-27_dp, “kg”): proton mass
PROTON_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent”, 1.503277593e-10_dp, 0.000000018e-10_dp, “J”): proton mass energy equivalent
PROTON_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent in MeV”, 938.2720813_dp, 0.0000058_dp, “MeV”): proton mass energy equivalent in MeV
PROTON_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“proton mass in u”, 1.007276466879_dp, 0.000000000091_dp, “u”): proton mass in u
PROTON_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“proton molar mass”, 1.007276466879e-3_dp, 0.000000000091e-3_dp, “kg mol^-1”): proton molar mass
PROTON_MUON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton-muon mass ratio”, 8.88024338_dp, 0.00000020_dp, “”): proton-muon mass ratio
PROTON_NEUTRON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mag. mom. ratio”, -1.45989805_dp, 0.00000034_dp, “”): proton-neutron mag. mom. ratio
PROTON_NEUTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mass ratio”, 0.99862347844_dp, 0.00000000051_dp, “”): proton-neutron mass ratio
PROTON_RMS_CHARGE_RADIUS_2014: type(codata_constant_type), parameter = codata_constant_type(“proton rms charge radius”, 0.8751e-15_dp, 0.0061e-15_dp, “m”): proton rms charge radius
PROTON_TAU_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“proton-tau mass ratio”, 0.528063_dp, 0.000048_dp, “”): proton-tau mass ratio
QUANTUM_OF_CIRCULATION_2014: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation”, 3.6369475486e-4_dp, 0.0000000017e-4_dp, “m^2 s^-1”): quantum of circulation
QUANTUM_OF_CIRCULATION_TIMES_2_2014: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation times 2”, 7.2738950972e-4_dp, 0.0000000033e-4_dp, “m^2 s^-1”): quantum of circulation times 2
RYDBERG_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant”, 10973731.568508_dp, 0.000065_dp, “m^-1”): Rydberg constant
RYDBERG_CONSTANT_TIMES_C_IN_HZ_2014: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times c in Hz”, 3.289841960355e15_dp, 0.000000000019e15_dp, “Hz”): Rydberg constant times c in Hz
RYDBERG_CONSTANT_TIMES_HC_IN_EV_2014: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in eV”, 13.605693009_dp, 0.000000084_dp, “eV”): Rydberg constant times hc in eV
RYDBERG_CONSTANT_TIMES_HC_IN_J_2014: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in J”, 2.179872325e-18_dp, 0.000000027e-18_dp, “J”): Rydberg constant times hc in J
SACKUR_TETRODE_CONSTANT_1_K_100_KPA_2014: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 100 kPa)”, -1.1517084_dp, 0.0000014_dp, “”): Sackur-Tetrode constant (1 K, 100 kPa)
SACKUR_TETRODE_CONSTANT_1_K_101_325_KPA_2014: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 101.325 kPa)”, -1.1648714_dp, 0.0000014_dp, “”): Sackur-Tetrode constant (1 K, 101.325 kPa)
SECOND_RADIATION_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“second radiation constant”, 1.43877736e-2_dp, 0.00000083e-2_dp, “m K”): second radiation constant
SHIELDED_HELION_GYROMAG_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio”, 2.037894585e8_dp, 0.000000027e8_dp, “s^-1 T^-1”): shielded helion gyromag. ratio
SHIELDED_HELION_GYROMAG_RATIO_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio over 2 pi”, 32.43409966_dp, 0.00000043_dp, “MHz T^-1”): shielded helion gyromag. ratio over 2 pi
SHIELDED_HELION_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom.”, -1.074553080e-26_dp, 0.000000014e-26_dp, “J T^-1”): shielded helion mag. mom.
SHIELDED_HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to Bohr magneton ratio”, -1.158671471e-3_dp, 0.000000014e-3_dp, “”): shielded helion mag. mom. to Bohr magneton ratio
SHIELDED_HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to nuclear magneton ratio”, -2.127497720_dp, 0.000000025_dp, “”): shielded helion mag. mom. to nuclear magneton ratio
SHIELDED_HELION_TO_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to proton mag. mom. ratio”, -0.7617665603_dp, 0.0000000092_dp, “”): shielded helion to proton mag. mom. ratio
SHIELDED_HELION_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to shielded proton mag. mom. ratio”, -0.7617861313_dp, 0.0000000033_dp, “”): shielded helion to shielded proton mag. mom. ratio
SHIELDED_PROTON_GYROMAG_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio”, 2.675153171e8_dp, 0.000000033e8_dp, “s^-1 T^-1”): shielded proton gyromag. ratio
SHIELDED_PROTON_GYROMAG_RATIO_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio over 2 pi”, 42.57638507_dp, 0.00000053_dp, “MHz T^-1”): shielded proton gyromag. ratio over 2 pi
SHIELDED_PROTON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom.”, 1.410570547e-26_dp, 0.000000018e-26_dp, “J T^-1”): shielded proton mag. mom.
SHIELDED_PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to Bohr magneton ratio”, 1.520993128e-3_dp, 0.000000017e-3_dp, “”): shielded proton mag. mom. to Bohr magneton ratio
SHIELDED_PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to nuclear magneton ratio”, 2.792775600_dp, 0.000000030_dp, “”): shielded proton mag. mom. to nuclear magneton ratio
SPEED_OF_LIGHT_IN_VACUUM_2014: type(codata_constant_type), parameter = codata_constant_type(“speed of light in vacuum”, 299792458_dp, 0.0_dp, “m s^-1”): speed of light in vacuum
STANDARD_ACCELERATION_OF_GRAVITY_2014: type(codata_constant_type), parameter = codata_constant_type(“standard acceleration of gravity”, 9.80665_dp, 0.0_dp, “m s^-2”): standard acceleration of gravity
STANDARD_ATMOSPHERE_2014: type(codata_constant_type), parameter = codata_constant_type(“standard atmosphere”, 101325_dp, 0.0_dp, “Pa”): standard atmosphere
STANDARD_STATE_PRESSURE_2014: type(codata_constant_type), parameter = codata_constant_type(“standard-state pressure”, 100000_dp, 0.0_dp, “Pa”): standard-state pressure
STEFAN_BOLTZMANN_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Stefan-Boltzmann constant”, 5.670367e-8_dp, 0.000013e-8_dp, “W m^-2 K^-4”): Stefan-Boltzmann constant
TAU_COMPTON_WAVELENGTH_2014: type(codata_constant_type), parameter = codata_constant_type(“tau Compton wavelength”, 0.697787e-15_dp, 0.000063e-15_dp, “m”): tau Compton wavelength
TAU_COMPTON_WAVELENGTH_OVER_2_PI_2014: type(codata_constant_type), parameter = codata_constant_type(“tau Compton wavelength over 2 pi”, 0.111056e-15_dp, 0.000010e-15_dp, “m”): tau Compton wavelength over 2 pi
TAU_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“tau-electron mass ratio”, 3477.15_dp, 0.31_dp, “”): tau-electron mass ratio
TAU_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“tau mass”, 3.16747e-27_dp, 0.00029e-27_dp, “kg”): tau mass
TAU_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“tau mass energy equivalent”, 2.84678e-10_dp, 0.00026e-10_dp, “J”): tau mass energy equivalent
TAU_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“tau mass energy equivalent in MeV”, 1776.82_dp, 0.16_dp, “MeV”): tau mass energy equivalent in MeV
TAU_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“tau mass in u”, 1.90749_dp, 0.00017_dp, “u”): tau mass in u
TAU_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“tau molar mass”, 1.90749e-3_dp, 0.00017e-3_dp, “kg mol^-1”): tau molar mass
TAU_MUON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“tau-muon mass ratio”, 16.8167_dp, 0.0015_dp, “”): tau-muon mass ratio
TAU_NEUTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“tau-neutron mass ratio”, 1.89111_dp, 0.00017_dp, “”): tau-neutron mass ratio
TAU_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“tau-proton mass ratio”, 1.89372_dp, 0.00017_dp, “”): tau-proton mass ratio
THOMSON_CROSS_SECTION_2014: type(codata_constant_type), parameter = codata_constant_type(“Thomson cross section”, 0.66524587158e-28_dp, 0.00000000091e-28_dp, “m^2”): Thomson cross section
TRITON_ELECTRON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“triton-electron mass ratio”, 5496.92153588_dp, 0.00000026_dp, “”): triton-electron mass ratio
TRITON_G_FACTOR_2014: type(codata_constant_type), parameter = codata_constant_type(“triton g factor”, 5.957924920_dp, 0.000000028_dp, “”): triton g factor
TRITON_MAG_MOM_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom.”, 1.504609503e-26_dp, 0.000000012e-26_dp, “J T^-1”): triton mag. mom.
TRITON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to Bohr magneton ratio”, 1.6223936616e-3_dp, 0.0000000076e-3_dp, “”): triton mag. mom. to Bohr magneton ratio
TRITON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to nuclear magneton ratio”, 2.978962460_dp, 0.000000014_dp, “”): triton mag. mom. to nuclear magneton ratio
TRITON_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mass”, 5.007356665e-27_dp, 0.000000062e-27_dp, “kg”): triton mass
TRITON_MASS_ENERGY_EQUIVALENT_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent”, 4.500387735e-10_dp, 0.000000055e-10_dp, “J”): triton mass energy equivalent
TRITON_MASS_ENERGY_EQUIVALENT_IN_MEV_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent in MeV”, 2808.921112_dp, 0.000017_dp, “MeV”): triton mass energy equivalent in MeV
TRITON_MASS_IN_U_2014: type(codata_constant_type), parameter = codata_constant_type(“triton mass in u”, 3.01550071632_dp, 0.00000000011_dp, “u”): triton mass in u
TRITON_MOLAR_MASS_2014: type(codata_constant_type), parameter = codata_constant_type(“triton molar mass”, 3.01550071632e-3_dp, 0.00000000011e-3_dp, “kg mol^-1”): triton molar mass
TRITON_PROTON_MASS_RATIO_2014: type(codata_constant_type), parameter = codata_constant_type(“triton-proton mass ratio”, 2.99371703348_dp, 0.00000000022_dp, “”): triton-proton mass ratio
UNIFIED_ATOMIC_MASS_UNIT_2014: type(codata_constant_type), parameter = codata_constant_type(“unified atomic mass unit”, 1.660539040e-27_dp, 0.000000020e-27_dp, “kg”): unified atomic mass unit
VON_KLITZING_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“von Klitzing constant”, 25812.8074555_dp, 0.0000059_dp, “ohm”): von Klitzing constant
WEAK_MIXING_ANGLE_2014: type(codata_constant_type), parameter = codata_constant_type(“weak mixing angle”, 0.2223_dp, 0.0021_dp, “”): weak mixing angle
WIEN_FREQUENCY_DISPLACEMENT_LAW_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Wien frequency displacement law constant”, 5.8789238e10_dp, 0.0000034e10_dp, “Hz K^-1”): Wien frequency displacement law constant
WIEN_WAVELENGTH_DISPLACEMENT_LAW_CONSTANT_2014: type(codata_constant_type), parameter = codata_constant_type(“Wien wavelength displacement law constant”, 2.8977729e-3_dp, 0.0000017e-3_dp, “m K”): Wien wavelength displacement law constant

\(\)

module codata__constants_2018: Codata Constants - Autogenerated
\(\)

Parameters

YEAR_2018: integer(kind=int32), parameter = 2018: Year of release.
ALPHA_PARTICLE_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-electron mass ratio”, 7294.29954142_dp, 0.00000024_dp, “”): alpha particle-electron mass ratio
ALPHA_PARTICLE_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass”, 6.6446573357e-27_dp, 0.0000000020e-27_dp, “kg”): alpha particle mass
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent”, 5.9719201914e-10_dp, 0.0000000018e-10_dp, “J”): alpha particle mass energy equivalent
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent in MeV”, 3727.3794066_dp, 0.0000011_dp, “MeV”): alpha particle mass energy equivalent in MeV
ALPHA_PARTICLE_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass in u”, 4.001506179127_dp, 0.000000000063_dp, “u”): alpha particle mass in u
ALPHA_PARTICLE_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle molar mass”, 4.0015061777e-3_dp, 0.0000000012e-3_dp, “kg mol^-1”): alpha particle molar mass
ALPHA_PARTICLE_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-proton mass ratio”, 3.97259969009_dp, 0.00000000022_dp, “”): alpha particle-proton mass ratio
ALPHA_PARTICLE_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“alpha particle relative atomic mass”, 4.001506179127_dp, 0.000000000063_dp, “”): alpha particle relative atomic mass
ANGSTROM_STAR_2018: type(codata_constant_type), parameter = codata_constant_type(“Angstrom star”, 1.00001495e-10_dp, 0.00000090e-10_dp, “m”): Angstrom star
ATOMIC_MASS_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant”, 1.66053906660e-27_dp, 0.00000000050e-27_dp, “kg”): atomic mass constant
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent”, 1.49241808560e-10_dp, 0.00000000045e-10_dp, “J”): atomic mass constant energy equivalent
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent in MeV”, 931.49410242_dp, 0.00000028_dp, “MeV”): atomic mass constant energy equivalent in MeV
ATOMIC_MASS_UNIT_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-electron volt relationship”, 9.3149410242e8_dp, 0.0000000028e8_dp, “eV”): atomic mass unit-electron volt relationship
ATOMIC_MASS_UNIT_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hartree relationship”, 3.4231776874e7_dp, 0.0000000010e7_dp, “E_h”): atomic mass unit-hartree relationship
ATOMIC_MASS_UNIT_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hertz relationship”, 2.25234271871e23_dp, 0.00000000068e23_dp, “Hz”): atomic mass unit-hertz relationship
ATOMIC_MASS_UNIT_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-inverse meter relationship”, 7.5130066104e14_dp, 0.0000000023e14_dp, “m^-1”): atomic mass unit-inverse meter relationship
ATOMIC_MASS_UNIT_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-joule relationship”, 1.49241808560e-10_dp, 0.00000000045e-10_dp, “J”): atomic mass unit-joule relationship
ATOMIC_MASS_UNIT_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kelvin relationship”, 1.08095401916e13_dp, 0.00000000033e13_dp, “K”): atomic mass unit-kelvin relationship
ATOMIC_MASS_UNIT_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kilogram relationship”, 1.66053906660e-27_dp, 0.00000000050e-27_dp, “kg”): atomic mass unit-kilogram relationship
ATOMIC_UNIT_OF_1ST_HYPERPOLARIZABILITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 1st hyperpolarizability”, 3.2063613061e-53_dp, 0.0000000015e-53_dp, “C^3 m^3 J^-2”): atomic unit of 1st hyperpolarizability
ATOMIC_UNIT_OF_2ND_HYPERPOLARIZABILITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 2nd hyperpolarizability”, 6.2353799905e-65_dp, 0.0000000038e-65_dp, “C^4 m^4 J^-3”): atomic unit of 2nd hyperpolarizability
ATOMIC_UNIT_OF_ACTION_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of action”, 1.054571817e-34_dp, 0.0_dp, “J s”): atomic unit of action
ATOMIC_UNIT_OF_CHARGE_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge”, 1.602176634e-19_dp, 0.0_dp, “C”): atomic unit of charge
ATOMIC_UNIT_OF_CHARGE_DENSITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge density”, 1.08120238457e12_dp, 0.00000000049e12_dp, “C m^-3”): atomic unit of charge density
ATOMIC_UNIT_OF_CURRENT_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of current”, 6.623618237510e-3_dp, 0.000000000013e-3_dp, “A”): atomic unit of current
ATOMIC_UNIT_OF_ELECTRIC_DIPOLE_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric dipole mom.”, 8.4783536255e-30_dp, 0.0000000013e-30_dp, “C m”): atomic unit of electric dipole mom.
ATOMIC_UNIT_OF_ELECTRIC_FIELD_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field”, 5.14220674763e11_dp, 0.00000000078e11_dp, “V m^-1”): atomic unit of electric field
ATOMIC_UNIT_OF_ELECTRIC_FIELD_GRADIENT_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field gradient”, 9.7173624292e21_dp, 0.0000000029e21_dp, “V m^-2”): atomic unit of electric field gradient
ATOMIC_UNIT_OF_ELECTRIC_POLARIZABILITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric polarizability”, 1.64877727436e-41_dp, 0.00000000050e-41_dp, “C^2 m^2 J^-1”): atomic unit of electric polarizability
ATOMIC_UNIT_OF_ELECTRIC_POTENTIAL_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric potential”, 27.211386245988_dp, 0.000000000053_dp, “V”): atomic unit of electric potential
ATOMIC_UNIT_OF_ELECTRIC_QUADRUPOLE_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric quadrupole mom.”, 4.4865515246e-40_dp, 0.0000000014e-40_dp, “C m^2”): atomic unit of electric quadrupole mom.
ATOMIC_UNIT_OF_ENERGY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of energy”, 4.3597447222071e-18_dp, 0.0000000000085e-18_dp, “J”): atomic unit of energy
ATOMIC_UNIT_OF_FORCE_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of force”, 8.2387234983e-8_dp, 0.0000000012e-8_dp, “N”): atomic unit of force
ATOMIC_UNIT_OF_LENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of length”, 5.29177210903e-11_dp, 0.00000000080e-11_dp, “m”): atomic unit of length
ATOMIC_UNIT_OF_MAG_DIPOLE_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. dipole mom.”, 1.85480201566e-23_dp, 0.00000000056e-23_dp, “J T^-1”): atomic unit of mag. dipole mom.
ATOMIC_UNIT_OF_MAG_FLUX_DENSITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. flux density”, 2.35051756758e5_dp, 0.00000000071e5_dp, “T”): atomic unit of mag. flux density
ATOMIC_UNIT_OF_MAGNETIZABILITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of magnetizability”, 7.8910366008e-29_dp, 0.0000000048e-29_dp, “J T^-2”): atomic unit of magnetizability
ATOMIC_UNIT_OF_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mass”, 9.1093837015e-31_dp, 0.0000000028e-31_dp, “kg”): atomic unit of mass
ATOMIC_UNIT_OF_MOMENTUM_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of momentum”, 1.99285191410e-24_dp, 0.00000000030e-24_dp, “kg m s^-1”): atomic unit of momentum
ATOMIC_UNIT_OF_PERMITTIVITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of permittivity”, 1.11265005545e-10_dp, 0.00000000017e-10_dp, “F m^-1”): atomic unit of permittivity
ATOMIC_UNIT_OF_TIME_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of time”, 2.4188843265857e-17_dp, 0.0000000000047e-17_dp, “s”): atomic unit of time
ATOMIC_UNIT_OF_VELOCITY_2018: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of velocity”, 2.18769126364e6_dp, 0.00000000033e6_dp, “m s^-1”): atomic unit of velocity
AVOGADRO_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Avogadro constant”, 6.02214076e23_dp, 0.0_dp, “mol^-1”): Avogadro constant
BOHR_MAGNETON_2018: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton”, 9.2740100783e-24_dp, 0.0000000028e-24_dp, “J T^-1”): Bohr magneton
BOHR_MAGNETON_IN_EV_T_2018: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in eV/T”, 5.7883818060e-5_dp, 0.0000000017e-5_dp, “eV T^-1”): Bohr magneton in eV/T
BOHR_MAGNETON_IN_HZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in Hz/T”, 1.39962449361e10_dp, 0.00000000042e10_dp, “Hz T^-1”): Bohr magneton in Hz/T
BOHR_MAGNETON_IN_INVERSE_METER_PER_TESLA_2018: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in inverse meter per tesla”, 46.686447783_dp, 0.000000014_dp, “m^-1 T^-1”): Bohr magneton in inverse meter per tesla
BOHR_MAGNETON_IN_K_T_2018: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in K/T”, 0.67171381563_dp, 0.00000000020_dp, “K T^-1”): Bohr magneton in K/T
BOHR_RADIUS_2018: type(codata_constant_type), parameter = codata_constant_type(“Bohr radius”, 5.29177210903e-11_dp, 0.00000000080e-11_dp, “m”): Bohr radius
BOLTZMANN_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant”, 1.380649e-23_dp, 0.0_dp, “J K^-1”): Boltzmann constant
BOLTZMANN_CONSTANT_IN_EV_K_2018: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in eV/K”, 8.617333262e-5_dp, 0.0_dp, “eV K^-1”): Boltzmann constant in eV/K
BOLTZMANN_CONSTANT_IN_HZ_K_2018: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in Hz/K”, 2.083661912e10_dp, 0.0_dp, “Hz K^-1”): Boltzmann constant in Hz/K
BOLTZMANN_CONSTANT_IN_INVERSE_METER_PER_KELVIN_2018: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in inverse meter per kelvin”, 69.50348004_dp, 0.0_dp, “m^-1 K^-1”): Boltzmann constant in inverse meter per kelvin
CHARACTERISTIC_IMPEDANCE_OF_VACUUM_2018: type(codata_constant_type), parameter = codata_constant_type(“characteristic impedance of vacuum”, 376.730313668_dp, 0.000000057_dp, “ohm”): characteristic impedance of vacuum
CLASSICAL_ELECTRON_RADIUS_2018: type(codata_constant_type), parameter = codata_constant_type(“classical electron radius”, 2.8179403262e-15_dp, 0.0000000013e-15_dp, “m”): classical electron radius
COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“Compton wavelength”, 2.42631023867e-12_dp, 0.00000000073e-12_dp, “m”): Compton wavelength
CONDUCTANCE_QUANTUM_2018: type(codata_constant_type), parameter = codata_constant_type(“conductance quantum”, 7.748091729e-5_dp, 0.0_dp, “S”): conductance quantum
CONVENTIONAL_VALUE_OF_AMPERE_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of ampere-90”, 1.00000008887_dp, 0.0_dp, “A”): conventional value of ampere-90
CONVENTIONAL_VALUE_OF_COULOMB_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of coulomb-90”, 1.00000008887_dp, 0.0_dp, “C”): conventional value of coulomb-90
CONVENTIONAL_VALUE_OF_FARAD_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of farad-90”, 0.99999998220_dp, 0.0_dp, “F”): conventional value of farad-90
CONVENTIONAL_VALUE_OF_HENRY_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of henry-90”, 1.00000001779_dp, 0.0_dp, “H”): conventional value of henry-90
CONVENTIONAL_VALUE_OF_JOSEPHSON_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of Josephson constant”, 483597.9e9_dp, 0.0_dp, “Hz V^-1”): conventional value of Josephson constant
CONVENTIONAL_VALUE_OF_OHM_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of ohm-90”, 1.00000001779_dp, 0.0_dp, “ohm”): conventional value of ohm-90
CONVENTIONAL_VALUE_OF_VOLT_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of volt-90”, 1.00000010666_dp, 0.0_dp, “V”): conventional value of volt-90
CONVENTIONAL_VALUE_OF_VON_KLITZING_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of von Klitzing constant”, 25812.807_dp, 0.0_dp, “ohm”): conventional value of von Klitzing constant
CONVENTIONAL_VALUE_OF_WATT_90_2018: type(codata_constant_type), parameter = codata_constant_type(“conventional value of watt-90”, 1.00000019553_dp, 0.0_dp, “W”): conventional value of watt-90
COPPER_X_UNIT_2018: type(codata_constant_type), parameter = codata_constant_type(“Copper x unit”, 1.00207697e-13_dp, 0.00000028e-13_dp, “m”): Copper x unit
DEUTERON_ELECTRON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mag. mom. ratio”, -4.664345551e-4_dp, 0.000000012e-4_dp, “”): deuteron-electron mag. mom. ratio
DEUTERON_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mass ratio”, 3670.48296788_dp, 0.00000013_dp, “”): deuteron-electron mass ratio
DEUTERON_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron g factor”, 0.8574382338_dp, 0.0000000022_dp, “”): deuteron g factor
DEUTERON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom.”, 4.330735094e-27_dp, 0.000000011e-27_dp, “J T^-1”): deuteron mag. mom.
DEUTERON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to Bohr magneton ratio”, 4.669754570e-4_dp, 0.000000012e-4_dp, “”): deuteron mag. mom. to Bohr magneton ratio
DEUTERON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to nuclear magneton ratio”, 0.8574382338_dp, 0.0000000022_dp, “”): deuteron mag. mom. to nuclear magneton ratio
DEUTERON_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass”, 3.3435837724e-27_dp, 0.0000000010e-27_dp, “kg”): deuteron mass
DEUTERON_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent”, 3.00506323102e-10_dp, 0.00000000091e-10_dp, “J”): deuteron mass energy equivalent
DEUTERON_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent in MeV”, 1875.61294257_dp, 0.00000057_dp, “MeV”): deuteron mass energy equivalent in MeV
DEUTERON_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass in u”, 2.013553212745_dp, 0.000000000040_dp, “u”): deuteron mass in u
DEUTERON_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron molar mass”, 2.01355321205e-3_dp, 0.00000000061e-3_dp, “kg mol^-1”): deuteron molar mass
DEUTERON_NEUTRON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron-neutron mag. mom. ratio”, -0.44820653_dp, 0.00000011_dp, “”): deuteron-neutron mag. mom. ratio
DEUTERON_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mag. mom. ratio”, 0.30701220939_dp, 0.00000000079_dp, “”): deuteron-proton mag. mom. ratio
DEUTERON_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mass ratio”, 1.99900750139_dp, 0.00000000011_dp, “”): deuteron-proton mass ratio
DEUTERON_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron relative atomic mass”, 2.013553212745_dp, 0.000000000040_dp, “”): deuteron relative atomic mass
DEUTERON_RMS_CHARGE_RADIUS_2018: type(codata_constant_type), parameter = codata_constant_type(“deuteron rms charge radius”, 2.12799e-15_dp, 0.00074e-15_dp, “m”): deuteron rms charge radius
ELECTRON_CHARGE_TO_MASS_QUOTIENT_2018: type(codata_constant_type), parameter = codata_constant_type(“electron charge to mass quotient”, -1.75882001076e11_dp, 0.00000000053e11_dp, “C kg^-1”): electron charge to mass quotient
ELECTRON_DEUTERON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mag. mom. ratio”, -2143.9234915_dp, 0.0000056_dp, “”): electron-deuteron mag. mom. ratio
ELECTRON_DEUTERON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mass ratio”, 2.724437107462e-4_dp, 0.000000000096e-4_dp, “”): electron-deuteron mass ratio
ELECTRON_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“electron g factor”, -2.00231930436256_dp, 0.00000000000035_dp, “”): electron g factor
ELECTRON_GYROMAG_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio”, 1.76085963023e11_dp, 0.00000000053e11_dp, “s^-1 T^-1”): electron gyromag. ratio
ELECTRON_GYROMAG_RATIO_IN_MHZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio in MHz/T”, 28024.9514242_dp, 0.0000085_dp, “MHz T^-1”): electron gyromag. ratio in MHz/T
ELECTRON_HELION_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-helion mass ratio”, 1.819543074573e-4_dp, 0.000000000079e-4_dp, “”): electron-helion mass ratio
ELECTRON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom.”, -9.2847647043e-24_dp, 0.0000000028e-24_dp, “J T^-1”): electron mag. mom.
ELECTRON_MAG_MOM_ANOMALY_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. anomaly”, 1.15965218128e-3_dp, 0.00000000018e-3_dp, “”): electron mag. mom. anomaly
ELECTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to Bohr magneton ratio”, -1.00115965218128_dp, 0.00000000000018_dp, “”): electron mag. mom. to Bohr magneton ratio
ELECTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to nuclear magneton ratio”, -1838.28197188_dp, 0.00000011_dp, “”): electron mag. mom. to nuclear magneton ratio
ELECTRON_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mass”, 9.1093837015e-31_dp, 0.0000000028e-31_dp, “kg”): electron mass
ELECTRON_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent”, 8.1871057769e-14_dp, 0.0000000025e-14_dp, “J”): electron mass energy equivalent
ELECTRON_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent in MeV”, 0.51099895000_dp, 0.00000000015_dp, “MeV”): electron mass energy equivalent in MeV
ELECTRON_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“electron mass in u”, 5.48579909065e-4_dp, 0.00000000016e-4_dp, “u”): electron mass in u
ELECTRON_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“electron molar mass”, 5.4857990888e-7_dp, 0.0000000017e-7_dp, “kg mol^-1”): electron molar mass
ELECTRON_MUON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mag. mom. ratio”, 206.7669883_dp, 0.0000046_dp, “”): electron-muon mag. mom. ratio
ELECTRON_MUON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mass ratio”, 4.83633169e-3_dp, 0.00000011e-3_dp, “”): electron-muon mass ratio
ELECTRON_NEUTRON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mag. mom. ratio”, 960.92050_dp, 0.00023_dp, “”): electron-neutron mag. mom. ratio
ELECTRON_NEUTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mass ratio”, 5.4386734424e-4_dp, 0.0000000026e-4_dp, “”): electron-neutron mass ratio
ELECTRON_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mag. mom. ratio”, -658.21068789_dp, 0.00000020_dp, “”): electron-proton mag. mom. ratio
ELECTRON_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mass ratio”, 5.44617021487e-4_dp, 0.00000000033e-4_dp, “”): electron-proton mass ratio
ELECTRON_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“electron relative atomic mass”, 5.48579909065e-4_dp, 0.00000000016e-4_dp, “”): electron relative atomic mass
ELECTRON_TAU_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-tau mass ratio”, 2.87585e-4_dp, 0.00019e-4_dp, “”): electron-tau mass ratio
ELECTRON_TO_ALPHA_PARTICLE_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron to alpha particle mass ratio”, 1.370933554787e-4_dp, 0.000000000045e-4_dp, “”): electron to alpha particle mass ratio
ELECTRON_TO_SHIELDED_HELION_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded helion mag. mom. ratio”, 864.058257_dp, 0.000010_dp, “”): electron to shielded helion mag. mom. ratio
ELECTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded proton mag. mom. ratio”, -658.2275971_dp, 0.0000072_dp, “”): electron to shielded proton mag. mom. ratio
ELECTRON_TRITON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“electron-triton mass ratio”, 1.819200062251e-4_dp, 0.000000000090e-4_dp, “”): electron-triton mass ratio
ELECTRON_VOLT_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt”, 1.602176634e-19_dp, 0.0_dp, “J”): electron volt
ELECTRON_VOLT_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-atomic mass unit relationship”, 1.07354410233e-9_dp, 0.00000000032e-9_dp, “u”): electron volt-atomic mass unit relationship
ELECTRON_VOLT_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hartree relationship”, 3.6749322175655e-2_dp, 0.0000000000071e-2_dp, “E_h”): electron volt-hartree relationship
ELECTRON_VOLT_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hertz relationship”, 2.417989242e14_dp, 0.0_dp, “Hz”): electron volt-hertz relationship
ELECTRON_VOLT_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-inverse meter relationship”, 8.065543937e5_dp, 0.0_dp, “m^-1”): electron volt-inverse meter relationship
ELECTRON_VOLT_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-joule relationship”, 1.602176634e-19_dp, 0.0_dp, “J”): electron volt-joule relationship
ELECTRON_VOLT_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kelvin relationship”, 1.160451812e4_dp, 0.0_dp, “K”): electron volt-kelvin relationship
ELECTRON_VOLT_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kilogram relationship”, 1.782661921e-36_dp, 0.0_dp, “kg”): electron volt-kilogram relationship
ELEMENTARY_CHARGE_2018: type(codata_constant_type), parameter = codata_constant_type(“elementary charge”, 1.602176634e-19_dp, 0.0_dp, “C”): elementary charge
ELEMENTARY_CHARGE_OVER_H_BAR_2018: type(codata_constant_type), parameter = codata_constant_type(“elementary charge over h-bar”, 1.519267447e15_dp, 0.0_dp, “A J^-1”): elementary charge over h-bar
FARADAY_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Faraday constant”, 96485.33212_dp, 0.0_dp, “C mol^-1”): Faraday constant
FERMI_COUPLING_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Fermi coupling constant”, 1.1663787e-5_dp, 0.0000006e-5_dp, “GeV^-2”): Fermi coupling constant
FINE_STRUCTURE_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“fine-structure constant”, 7.2973525693e-3_dp, 0.0000000011e-3_dp, “”): fine-structure constant
FIRST_RADIATION_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant”, 3.741771852e-16_dp, 0.0_dp, “W m^2”): first radiation constant
FIRST_RADIATION_CONSTANT_FOR_SPECTRAL_RADIANCE_2018: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant for spectral radiance”, 1.191042972e-16_dp, 0.0_dp, “W m^2 sr^-1”): first radiation constant for spectral radiance
HARTREE_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-atomic mass unit relationship”, 2.92126232205e-8_dp, 0.00000000088e-8_dp, “u”): hartree-atomic mass unit relationship
HARTREE_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-electron volt relationship”, 27.211386245988_dp, 0.000000000053_dp, “eV”): hartree-electron volt relationship
HARTREE_ENERGY_2018: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy”, 4.3597447222071e-18_dp, 0.0000000000085e-18_dp, “J”): Hartree energy
HARTREE_ENERGY_IN_EV_2018: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy in eV”, 27.211386245988_dp, 0.000000000053_dp, “eV”): Hartree energy in eV
HARTREE_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-hertz relationship”, 6.579683920502e15_dp, 0.000000000013e15_dp, “Hz”): hartree-hertz relationship
HARTREE_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-inverse meter relationship”, 2.1947463136320e7_dp, 0.0000000000043e7_dp, “m^-1”): hartree-inverse meter relationship
HARTREE_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-joule relationship”, 4.3597447222071e-18_dp, 0.0000000000085e-18_dp, “J”): hartree-joule relationship
HARTREE_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-kelvin relationship”, 3.1577502480407e5_dp, 0.0000000000061e5_dp, “K”): hartree-kelvin relationship
HARTREE_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hartree-kilogram relationship”, 4.8508702095432e-35_dp, 0.0000000000094e-35_dp, “kg”): hartree-kilogram relationship
HELION_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“helion-electron mass ratio”, 5495.88528007_dp, 0.00000024_dp, “”): helion-electron mass ratio
HELION_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“helion g factor”, -4.255250615_dp, 0.000000050_dp, “”): helion g factor
HELION_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom.”, -1.074617532e-26_dp, 0.000000013e-26_dp, “J T^-1”): helion mag. mom.
HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to Bohr magneton ratio”, -1.158740958e-3_dp, 0.000000014e-3_dp, “”): helion mag. mom. to Bohr magneton ratio
HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to nuclear magneton ratio”, -2.127625307_dp, 0.000000025_dp, “”): helion mag. mom. to nuclear magneton ratio
HELION_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mass”, 5.0064127796e-27_dp, 0.0000000015e-27_dp, “kg”): helion mass
HELION_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent”, 4.4995394125e-10_dp, 0.0000000014e-10_dp, “J”): helion mass energy equivalent
HELION_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent in MeV”, 2808.39160743_dp, 0.00000085_dp, “MeV”): helion mass energy equivalent in MeV
HELION_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“helion mass in u”, 3.014932247175_dp, 0.000000000097_dp, “u”): helion mass in u
HELION_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“helion molar mass”, 3.01493224613e-3_dp, 0.00000000091e-3_dp, “kg mol^-1”): helion molar mass
HELION_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“helion-proton mass ratio”, 2.99315267167_dp, 0.00000000013_dp, “”): helion-proton mass ratio
HELION_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“helion relative atomic mass”, 3.014932247175_dp, 0.000000000097_dp, “”): helion relative atomic mass
HELION_SHIELDING_SHIFT_2018: type(codata_constant_type), parameter = codata_constant_type(“helion shielding shift”, 5.996743e-5_dp, 0.000010e-5_dp, “”): helion shielding shift
HERTZ_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-atomic mass unit relationship”, 4.4398216652e-24_dp, 0.0000000013e-24_dp, “u”): hertz-atomic mass unit relationship
HERTZ_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-electron volt relationship”, 4.135667696e-15_dp, 0.0_dp, “eV”): hertz-electron volt relationship
HERTZ_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-hartree relationship”, 1.5198298460570e-16_dp, 0.0000000000029e-16_dp, “E_h”): hertz-hartree relationship
HERTZ_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-inverse meter relationship”, 3.335640951e-9_dp, 0.0_dp, “m^-1”): hertz-inverse meter relationship
HERTZ_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-joule relationship”, 6.62607015e-34_dp, 0.0_dp, “J”): hertz-joule relationship
HERTZ_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-kelvin relationship”, 4.799243073e-11_dp, 0.0_dp, “K”): hertz-kelvin relationship
HERTZ_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“hertz-kilogram relationship”, 7.372497323e-51_dp, 0.0_dp, “kg”): hertz-kilogram relationship
HYPERFINE_TRANSITION_FREQUENCY_OF_CS_133_2018: type(codata_constant_type), parameter = codata_constant_type(“hyperfine transition frequency of Cs-133”, 9192631770_dp, 0.0_dp, “Hz”): hyperfine transition frequency of Cs-133
INVERSE_FINE_STRUCTURE_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse fine-structure constant”, 137.035999084_dp, 0.000000021_dp, “”): inverse fine-structure constant
INVERSE_METER_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-atomic mass unit relationship”, 1.33102505010e-15_dp, 0.00000000040e-15_dp, “u”): inverse meter-atomic mass unit relationship
INVERSE_METER_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-electron volt relationship”, 1.239841984e-6_dp, 0.0_dp, “eV”): inverse meter-electron volt relationship
INVERSE_METER_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hartree relationship”, 4.5563352529120e-8_dp, 0.0000000000088e-8_dp, “E_h”): inverse meter-hartree relationship
INVERSE_METER_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hertz relationship”, 299792458_dp, 0.0_dp, “Hz”): inverse meter-hertz relationship
INVERSE_METER_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-joule relationship”, 1.986445857e-25_dp, 0.0_dp, “J”): inverse meter-joule relationship
INVERSE_METER_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kelvin relationship”, 1.438776877e-2_dp, 0.0_dp, “K”): inverse meter-kelvin relationship
INVERSE_METER_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kilogram relationship”, 2.210219094e-42_dp, 0.0_dp, “kg”): inverse meter-kilogram relationship
INVERSE_OF_CONDUCTANCE_QUANTUM_2018: type(codata_constant_type), parameter = codata_constant_type(“inverse of conductance quantum”, 12906.40372_dp, 0.0_dp, “ohm”): inverse of conductance quantum
JOSEPHSON_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Josephson constant”, 483597.8484e9_dp, 0.0_dp, “Hz V^-1”): Josephson constant
JOULE_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-atomic mass unit relationship”, 6.7005352565e9_dp, 0.0000000020e9_dp, “u”): joule-atomic mass unit relationship
JOULE_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-electron volt relationship”, 6.241509074e18_dp, 0.0_dp, “eV”): joule-electron volt relationship
JOULE_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-hartree relationship”, 2.2937122783963e17_dp, 0.0000000000045e17_dp, “E_h”): joule-hartree relationship
JOULE_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-hertz relationship”, 1.509190179e33_dp, 0.0_dp, “Hz”): joule-hertz relationship
JOULE_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-inverse meter relationship”, 5.034116567e24_dp, 0.0_dp, “m^-1”): joule-inverse meter relationship
JOULE_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-kelvin relationship”, 7.242970516e22_dp, 0.0_dp, “K”): joule-kelvin relationship
JOULE_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“joule-kilogram relationship”, 1.112650056e-17_dp, 0.0_dp, “kg”): joule-kilogram relationship
KELVIN_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-atomic mass unit relationship”, 9.2510873014e-14_dp, 0.0000000028e-14_dp, “u”): kelvin-atomic mass unit relationship
KELVIN_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-electron volt relationship”, 8.617333262e-5_dp, 0.0_dp, “eV”): kelvin-electron volt relationship
KELVIN_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hartree relationship”, 3.1668115634556e-6_dp, 0.0000000000061e-6_dp, “E_h”): kelvin-hartree relationship
KELVIN_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hertz relationship”, 2.083661912e10_dp, 0.0_dp, “Hz”): kelvin-hertz relationship
KELVIN_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-inverse meter relationship”, 69.50348004_dp, 0.0_dp, “m^-1”): kelvin-inverse meter relationship
KELVIN_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-joule relationship”, 1.380649e-23_dp, 0.0_dp, “J”): kelvin-joule relationship
KELVIN_KILOGRAM_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kelvin-kilogram relationship”, 1.536179187e-40_dp, 0.0_dp, “kg”): kelvin-kilogram relationship
KILOGRAM_ATOMIC_MASS_UNIT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-atomic mass unit relationship”, 6.0221407621e26_dp, 0.0000000018e26_dp, “u”): kilogram-atomic mass unit relationship
KILOGRAM_ELECTRON_VOLT_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-electron volt relationship”, 5.609588603e35_dp, 0.0_dp, “eV”): kilogram-electron volt relationship
KILOGRAM_HARTREE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hartree relationship”, 2.0614857887409e34_dp, 0.0000000000040e34_dp, “E_h”): kilogram-hartree relationship
KILOGRAM_HERTZ_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hertz relationship”, 1.356392489e50_dp, 0.0_dp, “Hz”): kilogram-hertz relationship
KILOGRAM_INVERSE_METER_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-inverse meter relationship”, 4.524438335e41_dp, 0.0_dp, “m^-1”): kilogram-inverse meter relationship
KILOGRAM_JOULE_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-joule relationship”, 8.987551787e16_dp, 0.0_dp, “J”): kilogram-joule relationship
KILOGRAM_KELVIN_RELATIONSHIP_2018: type(codata_constant_type), parameter = codata_constant_type(“kilogram-kelvin relationship”, 6.509657260e39_dp, 0.0_dp, “K”): kilogram-kelvin relationship
LATTICE_PARAMETER_OF_SILICON_2018: type(codata_constant_type), parameter = codata_constant_type(“lattice parameter of silicon”, 5.431020511e-10_dp, 0.000000089e-10_dp, “m”): lattice parameter of silicon
LATTICE_SPACING_OF_IDEAL_SI_220_2018: type(codata_constant_type), parameter = codata_constant_type(“lattice spacing of ideal Si (220)”, 1.920155716e-10_dp, 0.000000032e-10_dp, “m”): lattice spacing of ideal Si (220)
LOSCHMIDT_CONSTANT_273_15_K_100_KPA_2018: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 100 kPa)”, 2.651645804e25_dp, 0.0_dp, “m^-3”): Loschmidt constant (273.15 K, 100 kPa)
LOSCHMIDT_CONSTANT_273_15_K_101_325_KPA_2018: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 101.325 kPa)”, 2.686780111e25_dp, 0.0_dp, “m^-3”): Loschmidt constant (273.15 K, 101.325 kPa)
LUMINOUS_EFFICACY_2018: type(codata_constant_type), parameter = codata_constant_type(“luminous efficacy”, 683_dp, 0.0_dp, “lm W^-1”): luminous efficacy
MAG_FLUX_QUANTUM_2018: type(codata_constant_type), parameter = codata_constant_type(“mag. flux quantum”, 2.067833848e-15_dp, 0.0_dp, “Wb”): mag. flux quantum
MOLAR_GAS_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“molar gas constant”, 8.314462618_dp, 0.0_dp, “J mol^-1 K^-1”): molar gas constant
MOLAR_MASS_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“molar mass constant”, 0.99999999965e-3_dp, 0.00000000030e-3_dp, “kg mol^-1”): molar mass constant
MOLAR_MASS_OF_CARBON_12_2018: type(codata_constant_type), parameter = codata_constant_type(“molar mass of carbon-12”, 11.9999999958e-3_dp, 0.0000000036e-3_dp, “kg mol^-1”): molar mass of carbon-12
MOLAR_PLANCK_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“molar Planck constant”, 3.990312712e-10_dp, 0.0_dp, “J Hz^-1 mol^-1”): molar Planck constant
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_100_KPA_2018: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 100 kPa)”, 22.71095464e-3_dp, 0.0_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 100 kPa)
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_101_325_KPA_2018: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 101.325 kPa)”, 22.41396954e-3_dp, 0.0_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 101.325 kPa)
MOLAR_VOLUME_OF_SILICON_2018: type(codata_constant_type), parameter = codata_constant_type(“molar volume of silicon”, 1.205883199e-5_dp, 0.000000060e-5_dp, “m^3 mol^-1”): molar volume of silicon
MOLYBDENUM_X_UNIT_2018: type(codata_constant_type), parameter = codata_constant_type(“Molybdenum x unit”, 1.00209952e-13_dp, 0.00000053e-13_dp, “m”): Molybdenum x unit
MUON_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“muon Compton wavelength”, 1.173444110e-14_dp, 0.000000026e-14_dp, “m”): muon Compton wavelength
MUON_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon-electron mass ratio”, 206.7682830_dp, 0.0000046_dp, “”): muon-electron mass ratio
MUON_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“muon g factor”, -2.0023318418_dp, 0.0000000013_dp, “”): muon g factor
MUON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom.”, -4.49044830e-26_dp, 0.00000010e-26_dp, “J T^-1”): muon mag. mom.
MUON_MAG_MOM_ANOMALY_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. anomaly”, 1.16592089e-3_dp, 0.00000063e-3_dp, “”): muon mag. mom. anomaly
MUON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to Bohr magneton ratio”, -4.84197047e-3_dp, 0.00000011e-3_dp, “”): muon mag. mom. to Bohr magneton ratio
MUON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to nuclear magneton ratio”, -8.89059703_dp, 0.00000020_dp, “”): muon mag. mom. to nuclear magneton ratio
MUON_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mass”, 1.883531627e-28_dp, 0.000000042e-28_dp, “kg”): muon mass
MUON_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent”, 1.692833804e-11_dp, 0.000000038e-11_dp, “J”): muon mass energy equivalent
MUON_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent in MeV”, 105.6583755_dp, 0.0000023_dp, “MeV”): muon mass energy equivalent in MeV
MUON_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“muon mass in u”, 0.1134289259_dp, 0.0000000025_dp, “u”): muon mass in u
MUON_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“muon molar mass”, 1.134289259e-4_dp, 0.000000025e-4_dp, “kg mol^-1”): muon molar mass
MUON_NEUTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon-neutron mass ratio”, 0.1124545170_dp, 0.0000000025_dp, “”): muon-neutron mass ratio
MUON_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mag. mom. ratio”, -3.183345142_dp, 0.000000071_dp, “”): muon-proton mag. mom. ratio
MUON_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mass ratio”, 0.1126095264_dp, 0.0000000025_dp, “”): muon-proton mass ratio
MUON_TAU_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“muon-tau mass ratio”, 5.94635e-2_dp, 0.00040e-2_dp, “”): muon-tau mass ratio
NATURAL_UNIT_OF_ACTION_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action”, 1.054571817e-34_dp, 0.0_dp, “J s”): natural unit of action
NATURAL_UNIT_OF_ACTION_IN_EV_S_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action in eV s”, 6.582119569e-16_dp, 0.0_dp, “eV s”): natural unit of action in eV s
NATURAL_UNIT_OF_ENERGY_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy”, 8.1871057769e-14_dp, 0.0000000025e-14_dp, “J”): natural unit of energy
NATURAL_UNIT_OF_ENERGY_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy in MeV”, 0.51099895000_dp, 0.00000000015_dp, “MeV”): natural unit of energy in MeV
NATURAL_UNIT_OF_LENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of length”, 3.8615926796e-13_dp, 0.0000000012e-13_dp, “m”): natural unit of length
NATURAL_UNIT_OF_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mass”, 9.1093837015e-31_dp, 0.0000000028e-31_dp, “kg”): natural unit of mass
NATURAL_UNIT_OF_MOMENTUM_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of momentum”, 2.73092453075e-22_dp, 0.00000000082e-22_dp, “kg m s^-1”): natural unit of momentum
NATURAL_UNIT_OF_MOMENTUM_IN_MEV_C_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of momentum in MeV/c”, 0.51099895000_dp, 0.00000000015_dp, “MeV/c”): natural unit of momentum in MeV/c
NATURAL_UNIT_OF_TIME_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of time”, 1.28808866819e-21_dp, 0.00000000039e-21_dp, “s”): natural unit of time
NATURAL_UNIT_OF_VELOCITY_2018: type(codata_constant_type), parameter = codata_constant_type(“natural unit of velocity”, 299792458_dp, 0.0_dp, “m s^-1”): natural unit of velocity
NEUTRON_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron Compton wavelength”, 1.31959090581e-15_dp, 0.00000000075e-15_dp, “m”): neutron Compton wavelength
NEUTRON_ELECTRON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mag. mom. ratio”, 1.04066882e-3_dp, 0.00000025e-3_dp, “”): neutron-electron mag. mom. ratio
NEUTRON_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mass ratio”, 1838.68366173_dp, 0.00000089_dp, “”): neutron-electron mass ratio
NEUTRON_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron g factor”, -3.82608545_dp, 0.00000090_dp, “”): neutron g factor
NEUTRON_GYROMAG_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio”, 1.83247171e8_dp, 0.00000043e8_dp, “s^-1 T^-1”): neutron gyromag. ratio
NEUTRON_GYROMAG_RATIO_IN_MHZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio in MHz/T”, 29.1646931_dp, 0.0000069_dp, “MHz T^-1”): neutron gyromag. ratio in MHz/T
NEUTRON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom.”, -9.6623651e-27_dp, 0.0000023e-27_dp, “J T^-1”): neutron mag. mom.
NEUTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to Bohr magneton ratio”, -1.04187563e-3_dp, 0.00000025e-3_dp, “”): neutron mag. mom. to Bohr magneton ratio
NEUTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to nuclear magneton ratio”, -1.91304273_dp, 0.00000045_dp, “”): neutron mag. mom. to nuclear magneton ratio
NEUTRON_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mass”, 1.67492749804e-27_dp, 0.00000000095e-27_dp, “kg”): neutron mass
NEUTRON_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent”, 1.50534976287e-10_dp, 0.00000000086e-10_dp, “J”): neutron mass energy equivalent
NEUTRON_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent in MeV”, 939.56542052_dp, 0.00000054_dp, “MeV”): neutron mass energy equivalent in MeV
NEUTRON_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron mass in u”, 1.00866491595_dp, 0.00000000049_dp, “u”): neutron mass in u
NEUTRON_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron molar mass”, 1.00866491560e-3_dp, 0.00000000057e-3_dp, “kg mol^-1”): neutron molar mass
NEUTRON_MUON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-muon mass ratio”, 8.89248406_dp, 0.00000020_dp, “”): neutron-muon mass ratio
NEUTRON_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mag. mom. ratio”, -0.68497934_dp, 0.00000016_dp, “”): neutron-proton mag. mom. ratio
NEUTRON_PROTON_MASS_DIFFERENCE_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference”, 2.30557435e-30_dp, 0.00000082e-30_dp, “kg”): neutron-proton mass difference
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent”, 2.07214689e-13_dp, 0.00000074e-13_dp, “J”): neutron-proton mass difference energy equivalent
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent in MeV”, 1.29333236_dp, 0.00000046_dp, “MeV”): neutron-proton mass difference energy equivalent in MeV
NEUTRON_PROTON_MASS_DIFFERENCE_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference in u”, 1.38844933e-3_dp, 0.00000049e-3_dp, “u”): neutron-proton mass difference in u
NEUTRON_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass ratio”, 1.00137841931_dp, 0.00000000049_dp, “”): neutron-proton mass ratio
NEUTRON_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron relative atomic mass”, 1.00866491595_dp, 0.00000000049_dp, “”): neutron relative atomic mass
NEUTRON_TAU_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron-tau mass ratio”, 0.528779_dp, 0.000036_dp, “”): neutron-tau mass ratio
NEUTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“neutron to shielded proton mag. mom. ratio”, -0.68499694_dp, 0.00000016_dp, “”): neutron to shielded proton mag. mom. ratio
NEWTONIAN_CONSTANT_OF_GRAVITATION_2018: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation”, 6.67430e-11_dp, 0.00015e-11_dp, “m^3 kg^-1 s^-2”): Newtonian constant of gravitation
NEWTONIAN_CONSTANT_OF_GRAVITATION_OVER_H_BAR_C_2018: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation over h-bar c”, 6.70883e-39_dp, 0.00015e-39_dp, “(GeV/c^2)^-2”): Newtonian constant of gravitation over h-bar c
NUCLEAR_MAGNETON_2018: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton”, 5.0507837461e-27_dp, 0.0000000015e-27_dp, “J T^-1”): nuclear magneton
NUCLEAR_MAGNETON_IN_EV_T_2018: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in eV/T”, 3.15245125844e-8_dp, 0.00000000096e-8_dp, “eV T^-1”): nuclear magneton in eV/T
NUCLEAR_MAGNETON_IN_INVERSE_METER_PER_TESLA_2018: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in inverse meter per tesla”, 2.54262341353e-2_dp, 0.00000000078e-2_dp, “m^-1 T^-1”): nuclear magneton in inverse meter per tesla
NUCLEAR_MAGNETON_IN_K_T_2018: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in K/T”, 3.6582677756e-4_dp, 0.0000000011e-4_dp, “K T^-1”): nuclear magneton in K/T
NUCLEAR_MAGNETON_IN_MHZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in MHz/T”, 7.6225932291_dp, 0.0000000023_dp, “MHz T^-1”): nuclear magneton in MHz/T
PLANCK_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck constant”, 6.62607015e-34_dp, 0.0_dp, “J Hz^-1”): Planck constant
PLANCK_CONSTANT_IN_EV_HZ_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck constant in eV/Hz”, 4.135667696e-15_dp, 0.0_dp, “eV Hz^-1”): Planck constant in eV/Hz
PLANCK_LENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck length”, 1.616255e-35_dp, 0.000018e-35_dp, “m”): Planck length
PLANCK_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck mass”, 2.176434e-8_dp, 0.000024e-8_dp, “kg”): Planck mass
PLANCK_MASS_ENERGY_EQUIVALENT_IN_GEV_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck mass energy equivalent in GeV”, 1.220890e19_dp, 0.000014e19_dp, “GeV”): Planck mass energy equivalent in GeV
PLANCK_TEMPERATURE_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck temperature”, 1.416784e32_dp, 0.000016e32_dp, “K”): Planck temperature
PLANCK_TIME_2018: type(codata_constant_type), parameter = codata_constant_type(“Planck time”, 5.391247e-44_dp, 0.000060e-44_dp, “s”): Planck time
PROTON_CHARGE_TO_MASS_QUOTIENT_2018: type(codata_constant_type), parameter = codata_constant_type(“proton charge to mass quotient”, 9.5788331560e7_dp, 0.0000000029e7_dp, “C kg^-1”): proton charge to mass quotient
PROTON_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“proton Compton wavelength”, 1.32140985539e-15_dp, 0.00000000040e-15_dp, “m”): proton Compton wavelength
PROTON_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton-electron mass ratio”, 1836.15267343_dp, 0.00000011_dp, “”): proton-electron mass ratio
PROTON_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“proton g factor”, 5.5856946893_dp, 0.0000000016_dp, “”): proton g factor
PROTON_GYROMAG_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio”, 2.6752218744e8_dp, 0.0000000011e8_dp, “s^-1 T^-1”): proton gyromag. ratio
PROTON_GYROMAG_RATIO_IN_MHZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio in MHz/T”, 42.577478518_dp, 0.000000018_dp, “MHz T^-1”): proton gyromag. ratio in MHz/T
PROTON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom.”, 1.41060679736e-26_dp, 0.00000000060e-26_dp, “J T^-1”): proton mag. mom.
PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to Bohr magneton ratio”, 1.52103220230e-3_dp, 0.00000000046e-3_dp, “”): proton mag. mom. to Bohr magneton ratio
PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to nuclear magneton ratio”, 2.79284734463_dp, 0.00000000082_dp, “”): proton mag. mom. to nuclear magneton ratio
PROTON_MAG_SHIELDING_CORRECTION_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mag. shielding correction”, 2.5689e-5_dp, 0.0011e-5_dp, “”): proton mag. shielding correction
PROTON_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mass”, 1.67262192369e-27_dp, 0.00000000051e-27_dp, “kg”): proton mass
PROTON_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent”, 1.50327761598e-10_dp, 0.00000000046e-10_dp, “J”): proton mass energy equivalent
PROTON_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent in MeV”, 938.27208816_dp, 0.00000029_dp, “MeV”): proton mass energy equivalent in MeV
PROTON_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“proton mass in u”, 1.007276466621_dp, 0.000000000053_dp, “u”): proton mass in u
PROTON_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“proton molar mass”, 1.00727646627e-3_dp, 0.00000000031e-3_dp, “kg mol^-1”): proton molar mass
PROTON_MUON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton-muon mass ratio”, 8.88024337_dp, 0.00000020_dp, “”): proton-muon mass ratio
PROTON_NEUTRON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mag. mom. ratio”, -1.45989805_dp, 0.00000034_dp, “”): proton-neutron mag. mom. ratio
PROTON_NEUTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mass ratio”, 0.99862347812_dp, 0.00000000049_dp, “”): proton-neutron mass ratio
PROTON_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“proton relative atomic mass”, 1.007276466621_dp, 0.000000000053_dp, “”): proton relative atomic mass
PROTON_RMS_CHARGE_RADIUS_2018: type(codata_constant_type), parameter = codata_constant_type(“proton rms charge radius”, 8.414e-16_dp, 0.019e-16_dp, “m”): proton rms charge radius
PROTON_TAU_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“proton-tau mass ratio”, 0.528051_dp, 0.000036_dp, “”): proton-tau mass ratio
QUANTUM_OF_CIRCULATION_2018: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation”, 3.6369475516e-4_dp, 0.0000000011e-4_dp, “m^2 s^-1”): quantum of circulation
QUANTUM_OF_CIRCULATION_TIMES_2_2018: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation times 2”, 7.2738951032e-4_dp, 0.0000000022e-4_dp, “m^2 s^-1”): quantum of circulation times 2
REDUCED_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced Compton wavelength”, 3.8615926796e-13_dp, 0.0000000012e-13_dp, “m”): reduced Compton wavelength
REDUCED_MUON_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced muon Compton wavelength”, 1.867594306e-15_dp, 0.000000042e-15_dp, “m”): reduced muon Compton wavelength
REDUCED_NEUTRON_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced neutron Compton wavelength”, 2.1001941552e-16_dp, 0.0000000012e-16_dp, “m”): reduced neutron Compton wavelength
REDUCED_PLANCK_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced Planck constant”, 1.054571817e-34_dp, 0.0_dp, “J s”): reduced Planck constant
REDUCED_PLANCK_CONSTANT_IN_EV_S_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced Planck constant in eV s”, 6.582119569e-16_dp, 0.0_dp, “eV s”): reduced Planck constant in eV s
REDUCED_PLANCK_CONSTANT_TIMES_C_IN_MEV_FM_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced Planck constant times c in MeV fm”, 197.3269804_dp, 0.0_dp, “MeV fm”): reduced Planck constant times c in MeV fm
REDUCED_PROTON_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced proton Compton wavelength”, 2.10308910336e-16_dp, 0.00000000064e-16_dp, “m”): reduced proton Compton wavelength
REDUCED_TAU_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“reduced tau Compton wavelength”, 1.110538e-16_dp, 0.000075e-16_dp, “m”): reduced tau Compton wavelength
RYDBERG_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant”, 10973731.568160_dp, 0.000021_dp, “m^-1”): Rydberg constant
RYDBERG_CONSTANT_TIMES_C_IN_HZ_2018: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times c in Hz”, 3.2898419602508e15_dp, 0.0000000000064e15_dp, “Hz”): Rydberg constant times c in Hz
RYDBERG_CONSTANT_TIMES_HC_IN_EV_2018: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in eV”, 13.605693122994_dp, 0.000000000026_dp, “eV”): Rydberg constant times hc in eV
RYDBERG_CONSTANT_TIMES_HC_IN_J_2018: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in J”, 2.1798723611035e-18_dp, 0.0000000000042e-18_dp, “J”): Rydberg constant times hc in J
SACKUR_TETRODE_CONSTANT_1_K_100_KPA_2018: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 100 kPa)”, -1.15170753706_dp, 0.00000000045_dp, “”): Sackur-Tetrode constant (1 K, 100 kPa)
SACKUR_TETRODE_CONSTANT_1_K_101_325_KPA_2018: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 101.325 kPa)”, -1.16487052358_dp, 0.00000000045_dp, “”): Sackur-Tetrode constant (1 K, 101.325 kPa)
SECOND_RADIATION_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“second radiation constant”, 1.438776877e-2_dp, 0.0_dp, “m K”): second radiation constant
SHIELDED_HELION_GYROMAG_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio”, 2.037894569e8_dp, 0.000000024e8_dp, “s^-1 T^-1”): shielded helion gyromag. ratio
SHIELDED_HELION_GYROMAG_RATIO_IN_MHZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio in MHz/T”, 32.43409942_dp, 0.00000038_dp, “MHz T^-1”): shielded helion gyromag. ratio in MHz/T
SHIELDED_HELION_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom.”, -1.074553090e-26_dp, 0.000000013e-26_dp, “J T^-1”): shielded helion mag. mom.
SHIELDED_HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to Bohr magneton ratio”, -1.158671471e-3_dp, 0.000000014e-3_dp, “”): shielded helion mag. mom. to Bohr magneton ratio
SHIELDED_HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to nuclear magneton ratio”, -2.127497719_dp, 0.000000025_dp, “”): shielded helion mag. mom. to nuclear magneton ratio
SHIELDED_HELION_TO_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to proton mag. mom. ratio”, -0.7617665618_dp, 0.0000000089_dp, “”): shielded helion to proton mag. mom. ratio
SHIELDED_HELION_TO_SHIELDED_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to shielded proton mag. mom. ratio”, -0.7617861313_dp, 0.0000000033_dp, “”): shielded helion to shielded proton mag. mom. ratio
SHIELDED_PROTON_GYROMAG_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio”, 2.675153151e8_dp, 0.000000029e8_dp, “s^-1 T^-1”): shielded proton gyromag. ratio
SHIELDED_PROTON_GYROMAG_RATIO_IN_MHZ_T_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio in MHz/T”, 42.57638474_dp, 0.00000046_dp, “MHz T^-1”): shielded proton gyromag. ratio in MHz/T
SHIELDED_PROTON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom.”, 1.410570560e-26_dp, 0.000000015e-26_dp, “J T^-1”): shielded proton mag. mom.
SHIELDED_PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to Bohr magneton ratio”, 1.520993128e-3_dp, 0.000000017e-3_dp, “”): shielded proton mag. mom. to Bohr magneton ratio
SHIELDED_PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to nuclear magneton ratio”, 2.792775599_dp, 0.000000030_dp, “”): shielded proton mag. mom. to nuclear magneton ratio
SHIELDING_DIFFERENCE_OF_D_AND_P_IN_HD_2018: type(codata_constant_type), parameter = codata_constant_type(“shielding difference of d and p in HD”, 2.0200e-8_dp, 0.0020e-8_dp, “”): shielding difference of d and p in HD
SHIELDING_DIFFERENCE_OF_T_AND_P_IN_HT_2018: type(codata_constant_type), parameter = codata_constant_type(“shielding difference of t and p in HT”, 2.4140e-8_dp, 0.0020e-8_dp, “”): shielding difference of t and p in HT
SPEED_OF_LIGHT_IN_VACUUM_2018: type(codata_constant_type), parameter = codata_constant_type(“speed of light in vacuum”, 299792458_dp, 0.0_dp, “m s^-1”): speed of light in vacuum
STANDARD_ACCELERATION_OF_GRAVITY_2018: type(codata_constant_type), parameter = codata_constant_type(“standard acceleration of gravity”, 9.80665_dp, 0.0_dp, “m s^-2”): standard acceleration of gravity
STANDARD_ATMOSPHERE_2018: type(codata_constant_type), parameter = codata_constant_type(“standard atmosphere”, 101325_dp, 0.0_dp, “Pa”): standard atmosphere
STANDARD_STATE_PRESSURE_2018: type(codata_constant_type), parameter = codata_constant_type(“standard-state pressure”, 100000_dp, 0.0_dp, “Pa”): standard-state pressure
STEFAN_BOLTZMANN_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Stefan-Boltzmann constant”, 5.670374419e-8_dp, 0.0_dp, “W m^-2 K^-4”): Stefan-Boltzmann constant
TAU_COMPTON_WAVELENGTH_2018: type(codata_constant_type), parameter = codata_constant_type(“tau Compton wavelength”, 6.97771e-16_dp, 0.00047e-16_dp, “m”): tau Compton wavelength
TAU_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“tau-electron mass ratio”, 3477.23_dp, 0.23_dp, “”): tau-electron mass ratio
TAU_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“tau energy equivalent”, 1776.86_dp, 0.12_dp, “MeV”): tau energy equivalent
TAU_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“tau mass”, 3.16754e-27_dp, 0.00021e-27_dp, “kg”): tau mass
TAU_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“tau mass energy equivalent”, 2.84684e-10_dp, 0.00019e-10_dp, “J”): tau mass energy equivalent
TAU_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“tau mass in u”, 1.90754_dp, 0.00013_dp, “u”): tau mass in u
TAU_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“tau molar mass”, 1.90754e-3_dp, 0.00013e-3_dp, “kg mol^-1”): tau molar mass
TAU_MUON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“tau-muon mass ratio”, 16.8170_dp, 0.0011_dp, “”): tau-muon mass ratio
TAU_NEUTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“tau-neutron mass ratio”, 1.89115_dp, 0.00013_dp, “”): tau-neutron mass ratio
TAU_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“tau-proton mass ratio”, 1.89376_dp, 0.00013_dp, “”): tau-proton mass ratio
THOMSON_CROSS_SECTION_2018: type(codata_constant_type), parameter = codata_constant_type(“Thomson cross section”, 6.6524587321e-29_dp, 0.0000000060e-29_dp, “m^2”): Thomson cross section
TRITON_ELECTRON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“triton-electron mass ratio”, 5496.92153573_dp, 0.00000027_dp, “”): triton-electron mass ratio
TRITON_G_FACTOR_2018: type(codata_constant_type), parameter = codata_constant_type(“triton g factor”, 5.957924931_dp, 0.000000012_dp, “”): triton g factor
TRITON_MAG_MOM_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom.”, 1.5046095202e-26_dp, 0.0000000030e-26_dp, “J T^-1”): triton mag. mom.
TRITON_MAG_MOM_TO_BOHR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to Bohr magneton ratio”, 1.6223936651e-3_dp, 0.0000000032e-3_dp, “”): triton mag. mom. to Bohr magneton ratio
TRITON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to nuclear magneton ratio”, 2.9789624656_dp, 0.0000000059_dp, “”): triton mag. mom. to nuclear magneton ratio
TRITON_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mass”, 5.0073567446e-27_dp, 0.0000000015e-27_dp, “kg”): triton mass
TRITON_MASS_ENERGY_EQUIVALENT_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent”, 4.5003878060e-10_dp, 0.0000000014e-10_dp, “J”): triton mass energy equivalent
TRITON_MASS_ENERGY_EQUIVALENT_IN_MEV_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent in MeV”, 2808.92113298_dp, 0.00000085_dp, “MeV”): triton mass energy equivalent in MeV
TRITON_MASS_IN_U_2018: type(codata_constant_type), parameter = codata_constant_type(“triton mass in u”, 3.01550071621_dp, 0.00000000012_dp, “u”): triton mass in u
TRITON_MOLAR_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“triton molar mass”, 3.01550071517e-3_dp, 0.00000000092e-3_dp, “kg mol^-1”): triton molar mass
TRITON_PROTON_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“triton-proton mass ratio”, 2.99371703414_dp, 0.00000000015_dp, “”): triton-proton mass ratio
TRITON_RELATIVE_ATOMIC_MASS_2018: type(codata_constant_type), parameter = codata_constant_type(“triton relative atomic mass”, 3.01550071621_dp, 0.00000000012_dp, “”): triton relative atomic mass
TRITON_TO_PROTON_MAG_MOM_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“triton to proton mag. mom. ratio”, 1.0666399191_dp, 0.0000000021_dp, “”): triton to proton mag. mom. ratio
UNIFIED_ATOMIC_MASS_UNIT_2018: type(codata_constant_type), parameter = codata_constant_type(“unified atomic mass unit”, 1.66053906660e-27_dp, 0.00000000050e-27_dp, “kg”): unified atomic mass unit
VACUUM_ELECTRIC_PERMITTIVITY_2018: type(codata_constant_type), parameter = codata_constant_type(“vacuum electric permittivity”, 8.8541878128e-12_dp, 0.0000000013e-12_dp, “F m^-1”): vacuum electric permittivity
VACUUM_MAG_PERMEABILITY_2018: type(codata_constant_type), parameter = codata_constant_type(“vacuum mag. permeability”, 1.25663706212e-6_dp, 0.00000000019e-6_dp, “N A^-2”): vacuum mag. permeability
VON_KLITZING_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“von Klitzing constant”, 25812.80745_dp, 0.0_dp, “ohm”): von Klitzing constant
WEAK_MIXING_ANGLE_2018: type(codata_constant_type), parameter = codata_constant_type(“weak mixing angle”, 0.22290_dp, 0.00030_dp, “”): weak mixing angle
WIEN_FREQUENCY_DISPLACEMENT_LAW_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Wien frequency displacement law constant”, 5.878925757e10_dp, 0.0_dp, “Hz K^-1”): Wien frequency displacement law constant
WIEN_WAVELENGTH_DISPLACEMENT_LAW_CONSTANT_2018: type(codata_constant_type), parameter = codata_constant_type(“Wien wavelength displacement law constant”, 2.897771955e-3_dp, 0.0_dp, “m K”): Wien wavelength displacement law constant
W_TO_Z_MASS_RATIO_2018: type(codata_constant_type), parameter = codata_constant_type(“W to Z mass ratio”, 0.88153_dp, 0.00017_dp, “”): W to Z mass ratio

\(\)

module codata__constants_2022: Codata Constants - Autogenerated
\(\)

Parameters

YEAR: integer(kind=int32), parameter = 2022: Year of release.
ALPHA_PARTICLE_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-electron mass ratio”, 7294.29954171_dp, 0.00000017_dp, “”): alpha particle-electron mass ratio
ALPHA_PARTICLE_MASS: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass”, 6.6446573450e-27_dp, 0.0000000021e-27_dp, “kg”): alpha particle mass
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent”, 5.9719201997e-10_dp, 0.0000000019e-10_dp, “J”): alpha particle mass energy equivalent
ALPHA_PARTICLE_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass energy equivalent in MeV”, 3727.3794118_dp, 0.0000012_dp, “MeV”): alpha particle mass energy equivalent in MeV
ALPHA_PARTICLE_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“alpha particle mass in u”, 4.001506179129_dp, 0.000000000062_dp, “u”): alpha particle mass in u
ALPHA_PARTICLE_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“alpha particle molar mass”, 4.0015061833e-3_dp, 0.0000000012e-3_dp, “kg mol^-1”): alpha particle molar mass
ALPHA_PARTICLE_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“alpha particle-proton mass ratio”, 3.972599690252_dp, 0.000000000070_dp, “”): alpha particle-proton mass ratio
ALPHA_PARTICLE_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“alpha particle relative atomic mass”, 4.001506179129_dp, 0.000000000062_dp, “”): alpha particle relative atomic mass
ALPHA_PARTICLE_RMS_CHARGE_RADIUS: type(codata_constant_type), parameter = codata_constant_type(“alpha particle rms charge radius”, 1.6785e-15_dp, 0.0021e-15_dp, “m”): alpha particle rms charge radius
ANGSTROM_STAR: type(codata_constant_type), parameter = codata_constant_type(“Angstrom star”, 1.00001495e-10_dp, 0.00000090e-10_dp, “m”): Angstrom star
ATOMIC_MASS_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant”, 1.66053906892e-27_dp, 0.00000000052e-27_dp, “kg”): atomic mass constant
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent”, 1.49241808768e-10_dp, 0.00000000046e-10_dp, “J”): atomic mass constant energy equivalent
ATOMIC_MASS_CONSTANT_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“atomic mass constant energy equivalent in MeV”, 931.49410372_dp, 0.00000029_dp, “MeV”): atomic mass constant energy equivalent in MeV
ATOMIC_MASS_UNIT_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-electron volt relationship”, 9.3149410372e8_dp, 0.0000000029e8_dp, “eV”): atomic mass unit-electron volt relationship
ATOMIC_MASS_UNIT_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hartree relationship”, 3.4231776922e7_dp, 0.0000000011e7_dp, “E_h”): atomic mass unit-hartree relationship
ATOMIC_MASS_UNIT_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-hertz relationship”, 2.25234272185e23_dp, 0.00000000070e23_dp, “Hz”): atomic mass unit-hertz relationship
ATOMIC_MASS_UNIT_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-inverse meter relationship”, 7.5130066209e14_dp, 0.0000000023e14_dp, “m^-1”): atomic mass unit-inverse meter relationship
ATOMIC_MASS_UNIT_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-joule relationship”, 1.49241808768e-10_dp, 0.00000000046e-10_dp, “J”): atomic mass unit-joule relationship
ATOMIC_MASS_UNIT_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kelvin relationship”, 1.08095402067e13_dp, 0.00000000034e13_dp, “K”): atomic mass unit-kelvin relationship
ATOMIC_MASS_UNIT_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“atomic mass unit-kilogram relationship”, 1.66053906892e-27_dp, 0.00000000052e-27_dp, “kg”): atomic mass unit-kilogram relationship
ATOMIC_UNIT_OF_1ST_HYPERPOLARIZABILITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 1st hyperpolarizability”, 3.2063612996e-53_dp, 0.0000000015e-53_dp, “C^3 m^3 J^-2”): atomic unit of 1st hyperpolarizability
ATOMIC_UNIT_OF_2ND_HYPERPOLARIZABILITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of 2nd hyperpolarizability”, 6.2353799735e-65_dp, 0.0000000039e-65_dp, “C^4 m^4 J^-3”): atomic unit of 2nd hyperpolarizability
ATOMIC_UNIT_OF_ACTION: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of action”, 1.054571817e-34_dp, 0.0_dp, “J s”): atomic unit of action
ATOMIC_UNIT_OF_CHARGE: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge”, 1.602176634e-19_dp, 0.0_dp, “C”): atomic unit of charge
ATOMIC_UNIT_OF_CHARGE_DENSITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of charge density”, 1.08120238677e12_dp, 0.00000000051e12_dp, “C m^-3”): atomic unit of charge density
ATOMIC_UNIT_OF_CURRENT: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of current”, 6.6236182375082e-3_dp, 0.0000000000072e-3_dp, “A”): atomic unit of current
ATOMIC_UNIT_OF_ELECTRIC_DIPOLE_MOM: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric dipole mom.”, 8.4783536198e-30_dp, 0.0000000013e-30_dp, “C m”): atomic unit of electric dipole mom.
ATOMIC_UNIT_OF_ELECTRIC_FIELD: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field”, 5.14220675112e11_dp, 0.00000000080e11_dp, “V m^-1”): atomic unit of electric field
ATOMIC_UNIT_OF_ELECTRIC_FIELD_GRADIENT: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric field gradient”, 9.7173624424e21_dp, 0.0000000030e21_dp, “V m^-2”): atomic unit of electric field gradient
ATOMIC_UNIT_OF_ELECTRIC_POLARIZABILITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric polarizability”, 1.64877727212e-41_dp, 0.00000000051e-41_dp, “C^2 m^2 J^-1”): atomic unit of electric polarizability
ATOMIC_UNIT_OF_ELECTRIC_POTENTIAL: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric potential”, 27.211386245981_dp, 0.000000000030_dp, “V”): atomic unit of electric potential
ATOMIC_UNIT_OF_ELECTRIC_QUADRUPOLE_MOM: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of electric quadrupole mom.”, 4.4865515185e-40_dp, 0.0000000014e-40_dp, “C m^2”): atomic unit of electric quadrupole mom.
ATOMIC_UNIT_OF_ENERGY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of energy”, 4.3597447222060e-18_dp, 0.0000000000048e-18_dp, “J”): atomic unit of energy
ATOMIC_UNIT_OF_FORCE: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of force”, 8.2387235038e-8_dp, 0.0000000013e-8_dp, “N”): atomic unit of force
ATOMIC_UNIT_OF_LENGTH: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of length”, 5.29177210544e-11_dp, 0.00000000082e-11_dp, “m”): atomic unit of length
ATOMIC_UNIT_OF_MAG_DIPOLE_MOM: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. dipole mom.”, 1.85480201315e-23_dp, 0.00000000058e-23_dp, “J T^-1”): atomic unit of mag. dipole mom.
ATOMIC_UNIT_OF_MAG_FLUX_DENSITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mag. flux density”, 2.35051757077e5_dp, 0.00000000073e5_dp, “T”): atomic unit of mag. flux density
ATOMIC_UNIT_OF_MAGNETIZABILITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of magnetizability”, 7.8910365794e-29_dp, 0.0000000049e-29_dp, “J T^-2”): atomic unit of magnetizability
ATOMIC_UNIT_OF_MASS: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of mass”, 9.1093837139e-31_dp, 0.0000000028e-31_dp, “kg”): atomic unit of mass
ATOMIC_UNIT_OF_MOMENTUM: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of momentum”, 1.99285191545e-24_dp, 0.00000000031e-24_dp, “kg m s^-1”): atomic unit of momentum
ATOMIC_UNIT_OF_PERMITTIVITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of permittivity”, 1.11265005620e-10_dp, 0.00000000017e-10_dp, “F m^-1”): atomic unit of permittivity
ATOMIC_UNIT_OF_TIME: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of time”, 2.4188843265864e-17_dp, 0.0000000000026e-17_dp, “s”): atomic unit of time
ATOMIC_UNIT_OF_VELOCITY: type(codata_constant_type), parameter = codata_constant_type(“atomic unit of velocity”, 2.18769126216e6_dp, 0.00000000034e6_dp, “m s^-1”): atomic unit of velocity
AVOGADRO_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Avogadro constant”, 6.02214076e23_dp, 0.0_dp, “mol^-1”): Avogadro constant
BOHR_MAGNETON: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton”, 9.2740100657e-24_dp, 0.0000000029e-24_dp, “J T^-1”): Bohr magneton
BOHR_MAGNETON_IN_EV_T: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in eV/T”, 5.7883817982e-5_dp, 0.0000000018e-5_dp, “eV T^-1”): Bohr magneton in eV/T
BOHR_MAGNETON_IN_HZ_T: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in Hz/T”, 1.39962449171e10_dp, 0.00000000044e10_dp, “Hz T^-1”): Bohr magneton in Hz/T
BOHR_MAGNETON_IN_INVERSE_METER_PER_TESLA: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in inverse meter per tesla”, 46.686447719_dp, 0.000000015_dp, “m^-1 T^-1”): Bohr magneton in inverse meter per tesla
BOHR_MAGNETON_IN_K_T: type(codata_constant_type), parameter = codata_constant_type(“Bohr magneton in K/T”, 0.67171381472_dp, 0.00000000021_dp, “K T^-1”): Bohr magneton in K/T
BOHR_RADIUS: type(codata_constant_type), parameter = codata_constant_type(“Bohr radius”, 5.29177210544e-11_dp, 0.00000000082e-11_dp, “m”): Bohr radius
BOLTZMANN_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant”, 1.380649e-23_dp, 0.0_dp, “J K^-1”): Boltzmann constant
BOLTZMANN_CONSTANT_IN_EV_K: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in eV/K”, 8.617333262e-5_dp, 0.0_dp, “eV K^-1”): Boltzmann constant in eV/K
BOLTZMANN_CONSTANT_IN_HZ_K: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in Hz/K”, 2.083661912e10_dp, 0.0_dp, “Hz K^-1”): Boltzmann constant in Hz/K
BOLTZMANN_CONSTANT_IN_INVERSE_METER_PER_KELVIN: type(codata_constant_type), parameter = codata_constant_type(“Boltzmann constant in inverse meter per kelvin”, 69.50348004_dp, 0.0_dp, “m^-1 K^-1”): Boltzmann constant in inverse meter per kelvin
CHARACTERISTIC_IMPEDANCE_OF_VACUUM: type(codata_constant_type), parameter = codata_constant_type(“characteristic impedance of vacuum”, 376.730313412_dp, 0.000000059_dp, “ohm”): characteristic impedance of vacuum
CLASSICAL_ELECTRON_RADIUS: type(codata_constant_type), parameter = codata_constant_type(“classical electron radius”, 2.8179403205e-15_dp, 0.0000000013e-15_dp, “m”): classical electron radius
COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“Compton wavelength”, 2.42631023538e-12_dp, 0.00000000076e-12_dp, “m”): Compton wavelength
CONDUCTANCE_QUANTUM: type(codata_constant_type), parameter = codata_constant_type(“conductance quantum”, 7.748091729e-5_dp, 0.0_dp, “S”): conductance quantum
CONVENTIONAL_VALUE_OF_AMPERE_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of ampere-90”, 1.00000008887_dp, 0.0_dp, “A”): conventional value of ampere-90
CONVENTIONAL_VALUE_OF_COULOMB_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of coulomb-90”, 1.00000008887_dp, 0.0_dp, “C”): conventional value of coulomb-90
CONVENTIONAL_VALUE_OF_FARAD_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of farad-90”, 0.99999998220_dp, 0.0_dp, “F”): conventional value of farad-90
CONVENTIONAL_VALUE_OF_HENRY_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of henry-90”, 1.00000001779_dp, 0.0_dp, “H”): conventional value of henry-90
CONVENTIONAL_VALUE_OF_JOSEPHSON_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“conventional value of Josephson constant”, 483597.9e9_dp, 0.0_dp, “Hz V^-1”): conventional value of Josephson constant
CONVENTIONAL_VALUE_OF_OHM_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of ohm-90”, 1.00000001779_dp, 0.0_dp, “ohm”): conventional value of ohm-90
CONVENTIONAL_VALUE_OF_VOLT_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of volt-90”, 1.00000010666_dp, 0.0_dp, “V”): conventional value of volt-90
CONVENTIONAL_VALUE_OF_VON_KLITZING_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“conventional value of von Klitzing constant”, 25812.807_dp, 0.0_dp, “ohm”): conventional value of von Klitzing constant
CONVENTIONAL_VALUE_OF_WATT_90: type(codata_constant_type), parameter = codata_constant_type(“conventional value of watt-90”, 1.00000019553_dp, 0.0_dp, “W”): conventional value of watt-90
COPPER_X_UNIT: type(codata_constant_type), parameter = codata_constant_type(“Copper x unit”, 1.00207697e-13_dp, 0.00000028e-13_dp, “m”): Copper x unit
DEUTERON_ELECTRON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mag. mom. ratio”, -4.664345550e-4_dp, 0.000000012e-4_dp, “”): deuteron-electron mag. mom. ratio
DEUTERON_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron-electron mass ratio”, 3670.482967655_dp, 0.000000063_dp, “”): deuteron-electron mass ratio
DEUTERON_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“deuteron g factor”, 0.8574382335_dp, 0.0000000022_dp, “”): deuteron g factor
DEUTERON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom.”, 4.330735087e-27_dp, 0.000000011e-27_dp, “J T^-1”): deuteron mag. mom.
DEUTERON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to Bohr magneton ratio”, 4.669754568e-4_dp, 0.000000012e-4_dp, “”): deuteron mag. mom. to Bohr magneton ratio
DEUTERON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron mag. mom. to nuclear magneton ratio”, 0.8574382335_dp, 0.0000000022_dp, “”): deuteron mag. mom. to nuclear magneton ratio
DEUTERON_MASS: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass”, 3.3435837768e-27_dp, 0.0000000010e-27_dp, “kg”): deuteron mass
DEUTERON_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent”, 3.00506323491e-10_dp, 0.00000000094e-10_dp, “J”): deuteron mass energy equivalent
DEUTERON_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass energy equivalent in MeV”, 1875.61294500_dp, 0.00000058_dp, “MeV”): deuteron mass energy equivalent in MeV
DEUTERON_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“deuteron mass in u”, 2.013553212544_dp, 0.000000000015_dp, “u”): deuteron mass in u
DEUTERON_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“deuteron molar mass”, 2.01355321466e-3_dp, 0.00000000063e-3_dp, “kg mol^-1”): deuteron molar mass
DEUTERON_NEUTRON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron-neutron mag. mom. ratio”, -0.44820652_dp, 0.00000011_dp, “”): deuteron-neutron mag. mom. ratio
DEUTERON_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mag. mom. ratio”, 0.30701220930_dp, 0.00000000079_dp, “”): deuteron-proton mag. mom. ratio
DEUTERON_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“deuteron-proton mass ratio”, 1.9990075012699_dp, 0.0000000000084_dp, “”): deuteron-proton mass ratio
DEUTERON_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“deuteron relative atomic mass”, 2.013553212544_dp, 0.000000000015_dp, “”): deuteron relative atomic mass
DEUTERON_RMS_CHARGE_RADIUS: type(codata_constant_type), parameter = codata_constant_type(“deuteron rms charge radius”, 2.12778e-15_dp, 0.00027e-15_dp, “m”): deuteron rms charge radius
ELECTRON_CHARGE_TO_MASS_QUOTIENT: type(codata_constant_type), parameter = codata_constant_type(“electron charge to mass quotient”, -1.75882000838e11_dp, 0.00000000055e11_dp, “C kg^-1”): electron charge to mass quotient
ELECTRON_DEUTERON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mag. mom. ratio”, -2143.9234921_dp, 0.0000056_dp, “”): electron-deuteron mag. mom. ratio
ELECTRON_DEUTERON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-deuteron mass ratio”, 2.724437107629e-4_dp, 0.000000000047e-4_dp, “”): electron-deuteron mass ratio
ELECTRON_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“electron g factor”, -2.00231930436092_dp, 0.00000000000036_dp, “”): electron g factor
ELECTRON_GYROMAG_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio”, 1.76085962784e11_dp, 0.00000000055e11_dp, “s^-1 T^-1”): electron gyromag. ratio
ELECTRON_GYROMAG_RATIO_IN_MHZ_T: type(codata_constant_type), parameter = codata_constant_type(“electron gyromag. ratio in MHz/T”, 28024.9513861_dp, 0.0000087_dp, “MHz T^-1”): electron gyromag. ratio in MHz/T
ELECTRON_HELION_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-helion mass ratio”, 1.819543074649e-4_dp, 0.000000000053e-4_dp, “”): electron-helion mass ratio
ELECTRON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom.”, -9.2847646917e-24_dp, 0.0000000029e-24_dp, “J T^-1”): electron mag. mom.
ELECTRON_MAG_MOM_ANOMALY: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. anomaly”, 1.15965218046e-3_dp, 0.00000000018e-3_dp, “”): electron mag. mom. anomaly
ELECTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to Bohr magneton ratio”, -1.00115965218046_dp, 0.00000000000018_dp, “”): electron mag. mom. to Bohr magneton ratio
ELECTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron mag. mom. to nuclear magneton ratio”, -1838.281971877_dp, 0.000000032_dp, “”): electron mag. mom. to nuclear magneton ratio
ELECTRON_MASS: type(codata_constant_type), parameter = codata_constant_type(“electron mass”, 9.1093837139e-31_dp, 0.0000000028e-31_dp, “kg”): electron mass
ELECTRON_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent”, 8.1871057880e-14_dp, 0.0000000026e-14_dp, “J”): electron mass energy equivalent
ELECTRON_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“electron mass energy equivalent in MeV”, 0.51099895069_dp, 0.00000000016_dp, “MeV”): electron mass energy equivalent in MeV
ELECTRON_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“electron mass in u”, 5.485799090441e-4_dp, 0.000000000097e-4_dp, “u”): electron mass in u
ELECTRON_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“electron molar mass”, 5.4857990962e-7_dp, 0.0000000017e-7_dp, “kg mol^-1”): electron molar mass
ELECTRON_MUON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mag. mom. ratio”, 206.7669881_dp, 0.0000046_dp, “”): electron-muon mag. mom. ratio
ELECTRON_MUON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-muon mass ratio”, 4.83633170e-3_dp, 0.00000011e-3_dp, “”): electron-muon mass ratio
ELECTRON_NEUTRON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mag. mom. ratio”, 960.92048_dp, 0.00023_dp, “”): electron-neutron mag. mom. ratio
ELECTRON_NEUTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-neutron mass ratio”, 5.4386734416e-4_dp, 0.0000000022e-4_dp, “”): electron-neutron mass ratio
ELECTRON_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mag. mom. ratio”, -658.21068789_dp, 0.00000019_dp, “”): electron-proton mag. mom. ratio
ELECTRON_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-proton mass ratio”, 5.446170214889e-4_dp, 0.000000000094e-4_dp, “”): electron-proton mass ratio
ELECTRON_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“electron relative atomic mass”, 5.485799090441e-4_dp, 0.000000000097e-4_dp, “”): electron relative atomic mass
ELECTRON_TAU_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-tau mass ratio”, 2.87585e-4_dp, 0.00019e-4_dp, “”): electron-tau mass ratio
ELECTRON_TO_ALPHA_PARTICLE_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron to alpha particle mass ratio”, 1.370933554733e-4_dp, 0.000000000032e-4_dp, “”): electron to alpha particle mass ratio
ELECTRON_TO_SHIELDED_HELION_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded helion mag. mom. ratio”, 864.05823986_dp, 0.00000070_dp, “”): electron to shielded helion mag. mom. ratio
ELECTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron to shielded proton mag. mom. ratio”, -658.2275856_dp, 0.0000027_dp, “”): electron to shielded proton mag. mom. ratio
ELECTRON_TRITON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“electron-triton mass ratio”, 1.819200062327e-4_dp, 0.000000000068e-4_dp, “”): electron-triton mass ratio
ELECTRON_VOLT: type(codata_constant_type), parameter = codata_constant_type(“electron volt”, 1.602176634e-19_dp, 0.0_dp, “J”): electron volt
ELECTRON_VOLT_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-atomic mass unit relationship”, 1.07354410083e-9_dp, 0.00000000033e-9_dp, “u”): electron volt-atomic mass unit relationship
ELECTRON_VOLT_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hartree relationship”, 3.6749322175665e-2_dp, 0.0000000000040e-2_dp, “E_h”): electron volt-hartree relationship
ELECTRON_VOLT_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-hertz relationship”, 2.417989242e14_dp, 0.0_dp, “Hz”): electron volt-hertz relationship
ELECTRON_VOLT_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-inverse meter relationship”, 8.065543937e5_dp, 0.0_dp, “m^-1”): electron volt-inverse meter relationship
ELECTRON_VOLT_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-joule relationship”, 1.602176634e-19_dp, 0.0_dp, “J”): electron volt-joule relationship
ELECTRON_VOLT_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kelvin relationship”, 1.160451812e4_dp, 0.0_dp, “K”): electron volt-kelvin relationship
ELECTRON_VOLT_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“electron volt-kilogram relationship”, 1.782661921e-36_dp, 0.0_dp, “kg”): electron volt-kilogram relationship
ELEMENTARY_CHARGE: type(codata_constant_type), parameter = codata_constant_type(“elementary charge”, 1.602176634e-19_dp, 0.0_dp, “C”): elementary charge
ELEMENTARY_CHARGE_OVER_H_BAR: type(codata_constant_type), parameter = codata_constant_type(“elementary charge over h-bar”, 1.519267447e15_dp, 0.0_dp, “A J^-1”): elementary charge over h-bar
FARADAY_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Faraday constant”, 96485.33212_dp, 0.0_dp, “C mol^-1”): Faraday constant
FERMI_COUPLING_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Fermi coupling constant”, 1.1663787e-5_dp, 0.0000006e-5_dp, “GeV^-2”): Fermi coupling constant
FINE_STRUCTURE_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“fine-structure constant”, 7.2973525643e-3_dp, 0.0000000011e-3_dp, “”): fine-structure constant
FIRST_RADIATION_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant”, 3.741771852e-16_dp, 0.0_dp, “W m^2”): first radiation constant
FIRST_RADIATION_CONSTANT_FOR_SPECTRAL_RADIANCE: type(codata_constant_type), parameter = codata_constant_type(“first radiation constant for spectral radiance”, 1.191042972e-16_dp, 0.0_dp, “W m^2 sr^-1”): first radiation constant for spectral radiance
HARTREE_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-atomic mass unit relationship”, 2.92126231797e-8_dp, 0.00000000091e-8_dp, “u”): hartree-atomic mass unit relationship
HARTREE_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-electron volt relationship”, 27.211386245981_dp, 0.000000000030_dp, “eV”): hartree-electron volt relationship
HARTREE_ENERGY: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy”, 4.3597447222060e-18_dp, 0.0000000000048e-18_dp, “J”): Hartree energy
HARTREE_ENERGY_IN_EV: type(codata_constant_type), parameter = codata_constant_type(“Hartree energy in eV”, 27.211386245981_dp, 0.000000000030_dp, “eV”): Hartree energy in eV
HARTREE_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-hertz relationship”, 6.5796839204999e15_dp, 0.0000000000072e15_dp, “Hz”): hartree-hertz relationship
HARTREE_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-inverse meter relationship”, 2.1947463136314e7_dp, 0.0000000000024e7_dp, “m^-1”): hartree-inverse meter relationship
HARTREE_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-joule relationship”, 4.3597447222060e-18_dp, 0.0000000000048e-18_dp, “J”): hartree-joule relationship
HARTREE_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-kelvin relationship”, 3.1577502480398e5_dp, 0.0000000000034e5_dp, “K”): hartree-kelvin relationship
HARTREE_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hartree-kilogram relationship”, 4.8508702095419e-35_dp, 0.0000000000053e-35_dp, “kg”): hartree-kilogram relationship
HELION_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“helion-electron mass ratio”, 5495.88527984_dp, 0.00000016_dp, “”): helion-electron mass ratio
HELION_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“helion g factor”, -4.2552506995_dp, 0.0000000034_dp, “”): helion g factor
HELION_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom.”, -1.07461755198e-26_dp, 0.00000000093e-26_dp, “J T^-1”): helion mag. mom.
HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to Bohr magneton ratio”, -1.15874098083e-3_dp, 0.00000000094e-3_dp, “”): helion mag. mom. to Bohr magneton ratio
HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“helion mag. mom. to nuclear magneton ratio”, -2.1276253498_dp, 0.0000000017_dp, “”): helion mag. mom. to nuclear magneton ratio
HELION_MASS: type(codata_constant_type), parameter = codata_constant_type(“helion mass”, 5.0064127862e-27_dp, 0.0000000016e-27_dp, “kg”): helion mass
HELION_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent”, 4.4995394185e-10_dp, 0.0000000014e-10_dp, “J”): helion mass energy equivalent
HELION_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“helion mass energy equivalent in MeV”, 2808.39161112_dp, 0.00000088_dp, “MeV”): helion mass energy equivalent in MeV
HELION_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“helion mass in u”, 3.014932246932_dp, 0.000000000074_dp, “u”): helion mass in u
HELION_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“helion molar mass”, 3.01493225010e-3_dp, 0.00000000094e-3_dp, “kg mol^-1”): helion molar mass
HELION_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“helion-proton mass ratio”, 2.993152671552_dp, 0.000000000070_dp, “”): helion-proton mass ratio
HELION_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“helion relative atomic mass”, 3.014932246932_dp, 0.000000000074_dp, “”): helion relative atomic mass
HELION_SHIELDING_SHIFT: type(codata_constant_type), parameter = codata_constant_type(“helion shielding shift”, 5.9967029e-5_dp, 0.0000023e-5_dp, “”): helion shielding shift
HERTZ_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-atomic mass unit relationship”, 4.4398216590e-24_dp, 0.0000000014e-24_dp, “u”): hertz-atomic mass unit relationship
HERTZ_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-electron volt relationship”, 4.135667696e-15_dp, 0.0_dp, “eV”): hertz-electron volt relationship
HERTZ_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-hartree relationship”, 1.5198298460574e-16_dp, 0.0000000000017e-16_dp, “E_h”): hertz-hartree relationship
HERTZ_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-inverse meter relationship”, 3.335640951e-9_dp, 0.0_dp, “m^-1”): hertz-inverse meter relationship
HERTZ_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-joule relationship”, 6.62607015e-34_dp, 0.0_dp, “J”): hertz-joule relationship
HERTZ_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-kelvin relationship”, 4.799243073e-11_dp, 0.0_dp, “K”): hertz-kelvin relationship
HERTZ_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“hertz-kilogram relationship”, 7.372497323e-51_dp, 0.0_dp, “kg”): hertz-kilogram relationship
HYPERFINE_TRANSITION_FREQUENCY_OF_CS_133: type(codata_constant_type), parameter = codata_constant_type(“hyperfine transition frequency of Cs-133”, 9192631770_dp, 0.0_dp, “Hz”): hyperfine transition frequency of Cs-133
INVERSE_FINE_STRUCTURE_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“inverse fine-structure constant”, 137.035999177_dp, 0.000000021_dp, “”): inverse fine-structure constant
INVERSE_METER_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-atomic mass unit relationship”, 1.33102504824e-15_dp, 0.00000000041e-15_dp, “u”): inverse meter-atomic mass unit relationship
INVERSE_METER_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-electron volt relationship”, 1.239841984e-6_dp, 0.0_dp, “eV”): inverse meter-electron volt relationship
INVERSE_METER_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hartree relationship”, 4.5563352529132e-8_dp, 0.0000000000050e-8_dp, “E_h”): inverse meter-hartree relationship
INVERSE_METER_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-hertz relationship”, 299792458_dp, 0.0_dp, “Hz”): inverse meter-hertz relationship
INVERSE_METER_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-joule relationship”, 1.986445857e-25_dp, 0.0_dp, “J”): inverse meter-joule relationship
INVERSE_METER_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kelvin relationship”, 1.438776877e-2_dp, 0.0_dp, “K”): inverse meter-kelvin relationship
INVERSE_METER_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“inverse meter-kilogram relationship”, 2.210219094e-42_dp, 0.0_dp, “kg”): inverse meter-kilogram relationship
INVERSE_OF_CONDUCTANCE_QUANTUM: type(codata_constant_type), parameter = codata_constant_type(“inverse of conductance quantum”, 12906.40372_dp, 0.0_dp, “ohm”): inverse of conductance quantum
JOSEPHSON_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Josephson constant”, 483597.8484e9_dp, 0.0_dp, “Hz V^-1”): Josephson constant
JOULE_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-atomic mass unit relationship”, 6.7005352471e9_dp, 0.0000000021e9_dp, “u”): joule-atomic mass unit relationship
JOULE_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-electron volt relationship”, 6.241509074e18_dp, 0.0_dp, “eV”): joule-electron volt relationship
JOULE_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-hartree relationship”, 2.2937122783969e17_dp, 0.0000000000025e17_dp, “E_h”): joule-hartree relationship
JOULE_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-hertz relationship”, 1.509190179e33_dp, 0.0_dp, “Hz”): joule-hertz relationship
JOULE_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-inverse meter relationship”, 5.034116567e24_dp, 0.0_dp, “m^-1”): joule-inverse meter relationship
JOULE_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-kelvin relationship”, 7.242970516e22_dp, 0.0_dp, “K”): joule-kelvin relationship
JOULE_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“joule-kilogram relationship”, 1.112650056e-17_dp, 0.0_dp, “kg”): joule-kilogram relationship
KELVIN_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-atomic mass unit relationship”, 9.2510872884e-14_dp, 0.0000000029e-14_dp, “u”): kelvin-atomic mass unit relationship
KELVIN_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-electron volt relationship”, 8.617333262e-5_dp, 0.0_dp, “eV”): kelvin-electron volt relationship
KELVIN_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hartree relationship”, 3.1668115634564e-6_dp, 0.0000000000035e-6_dp, “E_h”): kelvin-hartree relationship
KELVIN_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-hertz relationship”, 2.083661912e10_dp, 0.0_dp, “Hz”): kelvin-hertz relationship
KELVIN_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-inverse meter relationship”, 69.50348004_dp, 0.0_dp, “m^-1”): kelvin-inverse meter relationship
KELVIN_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-joule relationship”, 1.380649e-23_dp, 0.0_dp, “J”): kelvin-joule relationship
KELVIN_KILOGRAM_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kelvin-kilogram relationship”, 1.536179187e-40_dp, 0.0_dp, “kg”): kelvin-kilogram relationship
KILOGRAM_ATOMIC_MASS_UNIT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-atomic mass unit relationship”, 6.0221407537e26_dp, 0.0000000019e26_dp, “u”): kilogram-atomic mass unit relationship
KILOGRAM_ELECTRON_VOLT_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-electron volt relationship”, 5.609588603e35_dp, 0.0_dp, “eV”): kilogram-electron volt relationship
KILOGRAM_HARTREE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hartree relationship”, 2.0614857887415e34_dp, 0.0000000000022e34_dp, “E_h”): kilogram-hartree relationship
KILOGRAM_HERTZ_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-hertz relationship”, 1.356392489e50_dp, 0.0_dp, “Hz”): kilogram-hertz relationship
KILOGRAM_INVERSE_METER_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-inverse meter relationship”, 4.524438335e41_dp, 0.0_dp, “m^-1”): kilogram-inverse meter relationship
KILOGRAM_JOULE_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-joule relationship”, 8.987551787e16_dp, 0.0_dp, “J”): kilogram-joule relationship
KILOGRAM_KELVIN_RELATIONSHIP: type(codata_constant_type), parameter = codata_constant_type(“kilogram-kelvin relationship”, 6.509657260e39_dp, 0.0_dp, “K”): kilogram-kelvin relationship
LATTICE_PARAMETER_OF_SILICON: type(codata_constant_type), parameter = codata_constant_type(“lattice parameter of silicon”, 5.431020511e-10_dp, 0.000000089e-10_dp, “m”): lattice parameter of silicon
LATTICE_SPACING_OF_IDEAL_SI_220: type(codata_constant_type), parameter = codata_constant_type(“lattice spacing of ideal Si (220)”, 1.920155716e-10_dp, 0.000000032e-10_dp, “m”): lattice spacing of ideal Si (220)
LOSCHMIDT_CONSTANT_273_15_K_100_KPA: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 100 kPa)”, 2.651645804e25_dp, 0.0_dp, “m^-3”): Loschmidt constant (273.15 K, 100 kPa)
LOSCHMIDT_CONSTANT_273_15_K_101_325_KPA: type(codata_constant_type), parameter = codata_constant_type(“Loschmidt constant (273.15 K, 101.325 kPa)”, 2.686780111e25_dp, 0.0_dp, “m^-3”): Loschmidt constant (273.15 K, 101.325 kPa)
LUMINOUS_EFFICACY: type(codata_constant_type), parameter = codata_constant_type(“luminous efficacy”, 683_dp, 0.0_dp, “lm W^-1”): luminous efficacy
MAG_FLUX_QUANTUM: type(codata_constant_type), parameter = codata_constant_type(“mag. flux quantum”, 2.067833848e-15_dp, 0.0_dp, “Wb”): mag. flux quantum
MOLAR_GAS_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“molar gas constant”, 8.314462618_dp, 0.0_dp, “J mol^-1 K^-1”): molar gas constant
MOLAR_MASS_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“molar mass constant”, 1.00000000105e-3_dp, 0.00000000031e-3_dp, “kg mol^-1”): molar mass constant
MOLAR_MASS_OF_CARBON_12: type(codata_constant_type), parameter = codata_constant_type(“molar mass of carbon-12”, 12.0000000126e-3_dp, 0.0000000037e-3_dp, “kg mol^-1”): molar mass of carbon-12
MOLAR_PLANCK_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“molar Planck constant”, 3.990312712e-10_dp, 0.0_dp, “J Hz^-1 mol^-1”): molar Planck constant
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_100_KPA: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 100 kPa)”, 22.71095464e-3_dp, 0.0_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 100 kPa)
MOLAR_VOLUME_OF_IDEAL_GAS_273_15_K_101_325_KPA: type(codata_constant_type), parameter = codata_constant_type(“molar volume of ideal gas (273.15 K, 101.325 kPa)”, 22.41396954e-3_dp, 0.0_dp, “m^3 mol^-1”): molar volume of ideal gas (273.15 K, 101.325 kPa)
MOLAR_VOLUME_OF_SILICON: type(codata_constant_type), parameter = codata_constant_type(“molar volume of silicon”, 1.205883199e-5_dp, 0.000000060e-5_dp, “m^3 mol^-1”): molar volume of silicon
MOLYBDENUM_X_UNIT: type(codata_constant_type), parameter = codata_constant_type(“Molybdenum x unit”, 1.00209952e-13_dp, 0.00000053e-13_dp, “m”): Molybdenum x unit
MUON_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“muon Compton wavelength”, 1.173444110e-14_dp, 0.000000026e-14_dp, “m”): muon Compton wavelength
MUON_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon-electron mass ratio”, 206.7682827_dp, 0.0000046_dp, “”): muon-electron mass ratio
MUON_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“muon g factor”, -2.00233184123_dp, 0.00000000082_dp, “”): muon g factor
MUON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom.”, -4.49044830e-26_dp, 0.00000010e-26_dp, “J T^-1”): muon mag. mom.
MUON_MAG_MOM_ANOMALY: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. anomaly”, 1.16592062e-3_dp, 0.00000041e-3_dp, “”): muon mag. mom. anomaly
MUON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to Bohr magneton ratio”, -4.84197048e-3_dp, 0.00000011e-3_dp, “”): muon mag. mom. to Bohr magneton ratio
MUON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon mag. mom. to nuclear magneton ratio”, -8.89059704_dp, 0.00000020_dp, “”): muon mag. mom. to nuclear magneton ratio
MUON_MASS: type(codata_constant_type), parameter = codata_constant_type(“muon mass”, 1.883531627e-28_dp, 0.000000042e-28_dp, “kg”): muon mass
MUON_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent”, 1.692833804e-11_dp, 0.000000038e-11_dp, “J”): muon mass energy equivalent
MUON_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“muon mass energy equivalent in MeV”, 105.6583755_dp, 0.0000023_dp, “MeV”): muon mass energy equivalent in MeV
MUON_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“muon mass in u”, 0.1134289257_dp, 0.0000000025_dp, “u”): muon mass in u
MUON_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“muon molar mass”, 1.134289258e-4_dp, 0.000000025e-4_dp, “kg mol^-1”): muon molar mass
MUON_NEUTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon-neutron mass ratio”, 0.1124545168_dp, 0.0000000025_dp, “”): muon-neutron mass ratio
MUON_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mag. mom. ratio”, -3.183345146_dp, 0.000000071_dp, “”): muon-proton mag. mom. ratio
MUON_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon-proton mass ratio”, 0.1126095262_dp, 0.0000000025_dp, “”): muon-proton mass ratio
MUON_TAU_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“muon-tau mass ratio”, 5.94635e-2_dp, 0.00040e-2_dp, “”): muon-tau mass ratio
NATURAL_UNIT_OF_ACTION: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action”, 1.054571817e-34_dp, 0.0_dp, “J s”): natural unit of action
NATURAL_UNIT_OF_ACTION_IN_EV_S: type(codata_constant_type), parameter = codata_constant_type(“natural unit of action in eV s”, 6.582119569e-16_dp, 0.0_dp, “eV s”): natural unit of action in eV s
NATURAL_UNIT_OF_ENERGY: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy”, 8.1871057880e-14_dp, 0.0000000026e-14_dp, “J”): natural unit of energy
NATURAL_UNIT_OF_ENERGY_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“natural unit of energy in MeV”, 0.51099895069_dp, 0.00000000016_dp, “MeV”): natural unit of energy in MeV
NATURAL_UNIT_OF_LENGTH: type(codata_constant_type), parameter = codata_constant_type(“natural unit of length”, 3.8615926744e-13_dp, 0.0000000012e-13_dp, “m”): natural unit of length
NATURAL_UNIT_OF_MASS: type(codata_constant_type), parameter = codata_constant_type(“natural unit of mass”, 9.1093837139e-31_dp, 0.0000000028e-31_dp, “kg”): natural unit of mass
NATURAL_UNIT_OF_MOMENTUM: type(codata_constant_type), parameter = codata_constant_type(“natural unit of momentum”, 2.73092453446e-22_dp, 0.00000000085e-22_dp, “kg m s^-1”): natural unit of momentum
NATURAL_UNIT_OF_MOMENTUM_IN_MEV_C: type(codata_constant_type), parameter = codata_constant_type(“natural unit of momentum in MeV/c”, 0.51099895069_dp, 0.00000000016_dp, “MeV/c”): natural unit of momentum in MeV/c
NATURAL_UNIT_OF_TIME: type(codata_constant_type), parameter = codata_constant_type(“natural unit of time”, 1.28808866644e-21_dp, 0.00000000040e-21_dp, “s”): natural unit of time
NATURAL_UNIT_OF_VELOCITY: type(codata_constant_type), parameter = codata_constant_type(“natural unit of velocity”, 299792458_dp, 0.0_dp, “m s^-1”): natural unit of velocity
NEUTRON_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“neutron Compton wavelength”, 1.31959090382e-15_dp, 0.00000000067e-15_dp, “m”): neutron Compton wavelength
NEUTRON_ELECTRON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mag. mom. ratio”, 1.04066884e-3_dp, 0.00000024e-3_dp, “”): neutron-electron mag. mom. ratio
NEUTRON_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron-electron mass ratio”, 1838.68366200_dp, 0.00000074_dp, “”): neutron-electron mass ratio
NEUTRON_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“neutron g factor”, -3.82608552_dp, 0.00000090_dp, “”): neutron g factor
NEUTRON_GYROMAG_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio”, 1.83247174e8_dp, 0.00000043e8_dp, “s^-1 T^-1”): neutron gyromag. ratio
NEUTRON_GYROMAG_RATIO_IN_MHZ_T: type(codata_constant_type), parameter = codata_constant_type(“neutron gyromag. ratio in MHz/T”, 29.1646935_dp, 0.0000069_dp, “MHz T^-1”): neutron gyromag. ratio in MHz/T
NEUTRON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom.”, -9.6623653e-27_dp, 0.0000023e-27_dp, “J T^-1”): neutron mag. mom.
NEUTRON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to Bohr magneton ratio”, -1.04187565e-3_dp, 0.00000025e-3_dp, “”): neutron mag. mom. to Bohr magneton ratio
NEUTRON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron mag. mom. to nuclear magneton ratio”, -1.91304276_dp, 0.00000045_dp, “”): neutron mag. mom. to nuclear magneton ratio
NEUTRON_MASS: type(codata_constant_type), parameter = codata_constant_type(“neutron mass”, 1.67492750056e-27_dp, 0.00000000085e-27_dp, “kg”): neutron mass
NEUTRON_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent”, 1.50534976514e-10_dp, 0.00000000076e-10_dp, “J”): neutron mass energy equivalent
NEUTRON_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“neutron mass energy equivalent in MeV”, 939.56542194_dp, 0.00000048_dp, “MeV”): neutron mass energy equivalent in MeV
NEUTRON_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“neutron mass in u”, 1.00866491606_dp, 0.00000000040_dp, “u”): neutron mass in u
NEUTRON_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“neutron molar mass”, 1.00866491712e-3_dp, 0.00000000051e-3_dp, “kg mol^-1”): neutron molar mass
NEUTRON_MUON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron-muon mass ratio”, 8.89248408_dp, 0.00000020_dp, “”): neutron-muon mass ratio
NEUTRON_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mag. mom. ratio”, -0.68497935_dp, 0.00000016_dp, “”): neutron-proton mag. mom. ratio
NEUTRON_PROTON_MASS_DIFFERENCE: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference”, 2.30557461e-30_dp, 0.00000067e-30_dp, “kg”): neutron-proton mass difference
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent”, 2.07214712e-13_dp, 0.00000060e-13_dp, “J”): neutron-proton mass difference energy equivalent
NEUTRON_PROTON_MASS_DIFFERENCE_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference energy equivalent in MeV”, 1.29333251_dp, 0.00000038_dp, “MeV”): neutron-proton mass difference energy equivalent in MeV
NEUTRON_PROTON_MASS_DIFFERENCE_IN_U: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass difference in u”, 1.38844948e-3_dp, 0.00000040e-3_dp, “u”): neutron-proton mass difference in u
NEUTRON_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron-proton mass ratio”, 1.00137841946_dp, 0.00000000040_dp, “”): neutron-proton mass ratio
NEUTRON_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“neutron relative atomic mass”, 1.00866491606_dp, 0.00000000040_dp, “”): neutron relative atomic mass
NEUTRON_TAU_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron-tau mass ratio”, 0.528779_dp, 0.000036_dp, “”): neutron-tau mass ratio
NEUTRON_TO_SHIELDED_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“neutron to shielded proton mag. mom. ratio”, -0.68499694_dp, 0.00000016_dp, “”): neutron to shielded proton mag. mom. ratio
NEWTONIAN_CONSTANT_OF_GRAVITATION: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation”, 6.67430e-11_dp, 0.00015e-11_dp, “m^3 kg^-1 s^-2”): Newtonian constant of gravitation
NEWTONIAN_CONSTANT_OF_GRAVITATION_OVER_H_BAR_C: type(codata_constant_type), parameter = codata_constant_type(“Newtonian constant of gravitation over h-bar c”, 6.70883e-39_dp, 0.00015e-39_dp, “(GeV/c^2)^-2”): Newtonian constant of gravitation over h-bar c
NUCLEAR_MAGNETON: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton”, 5.0507837393e-27_dp, 0.0000000016e-27_dp, “J T^-1”): nuclear magneton
NUCLEAR_MAGNETON_IN_EV_T: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in eV/T”, 3.15245125417e-8_dp, 0.00000000098e-8_dp, “eV T^-1”): nuclear magneton in eV/T
NUCLEAR_MAGNETON_IN_INVERSE_METER_PER_TESLA: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in inverse meter per tesla”, 2.54262341009e-2_dp, 0.00000000079e-2_dp, “m^-1 T^-1”): nuclear magneton in inverse meter per tesla
NUCLEAR_MAGNETON_IN_K_T: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in K/T”, 3.6582677706e-4_dp, 0.0000000011e-4_dp, “K T^-1”): nuclear magneton in K/T
NUCLEAR_MAGNETON_IN_MHZ_T: type(codata_constant_type), parameter = codata_constant_type(“nuclear magneton in MHz/T”, 7.6225932188_dp, 0.0000000024_dp, “MHz T^-1”): nuclear magneton in MHz/T
PLANCK_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Planck constant”, 6.62607015e-34_dp, 0.0_dp, “J Hz^-1”): Planck constant
PLANCK_CONSTANT_IN_EV_HZ: type(codata_constant_type), parameter = codata_constant_type(“Planck constant in eV/Hz”, 4.135667696e-15_dp, 0.0_dp, “eV Hz^-1”): Planck constant in eV/Hz
PLANCK_LENGTH: type(codata_constant_type), parameter = codata_constant_type(“Planck length”, 1.616255e-35_dp, 0.000018e-35_dp, “m”): Planck length
PLANCK_MASS: type(codata_constant_type), parameter = codata_constant_type(“Planck mass”, 2.176434e-8_dp, 0.000024e-8_dp, “kg”): Planck mass
PLANCK_MASS_ENERGY_EQUIVALENT_IN_GEV: type(codata_constant_type), parameter = codata_constant_type(“Planck mass energy equivalent in GeV”, 1.220890e19_dp, 0.000014e19_dp, “GeV”): Planck mass energy equivalent in GeV
PLANCK_TEMPERATURE: type(codata_constant_type), parameter = codata_constant_type(“Planck temperature”, 1.416784e32_dp, 0.000016e32_dp, “K”): Planck temperature
PLANCK_TIME: type(codata_constant_type), parameter = codata_constant_type(“Planck time”, 5.391247e-44_dp, 0.000060e-44_dp, “s”): Planck time
PROTON_CHARGE_TO_MASS_QUOTIENT: type(codata_constant_type), parameter = codata_constant_type(“proton charge to mass quotient”, 9.5788331430e7_dp, 0.0000000030e7_dp, “C kg^-1”): proton charge to mass quotient
PROTON_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“proton Compton wavelength”, 1.32140985360e-15_dp, 0.00000000041e-15_dp, “m”): proton Compton wavelength
PROTON_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton-electron mass ratio”, 1836.152673426_dp, 0.000000032_dp, “”): proton-electron mass ratio
PROTON_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“proton g factor”, 5.5856946893_dp, 0.0000000016_dp, “”): proton g factor
PROTON_GYROMAG_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio”, 2.6752218708e8_dp, 0.0000000011e8_dp, “s^-1 T^-1”): proton gyromag. ratio
PROTON_GYROMAG_RATIO_IN_MHZ_T: type(codata_constant_type), parameter = codata_constant_type(“proton gyromag. ratio in MHz/T”, 42.577478461_dp, 0.000000018_dp, “MHz T^-1”): proton gyromag. ratio in MHz/T
PROTON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom.”, 1.41060679545e-26_dp, 0.00000000060e-26_dp, “J T^-1”): proton mag. mom.
PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to Bohr magneton ratio”, 1.52103220230e-3_dp, 0.00000000045e-3_dp, “”): proton mag. mom. to Bohr magneton ratio
PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton mag. mom. to nuclear magneton ratio”, 2.79284734463_dp, 0.00000000082_dp, “”): proton mag. mom. to nuclear magneton ratio
PROTON_MAG_SHIELDING_CORRECTION: type(codata_constant_type), parameter = codata_constant_type(“proton mag. shielding correction”, 2.56715e-5_dp, 0.00041e-5_dp, “”): proton mag. shielding correction
PROTON_MASS: type(codata_constant_type), parameter = codata_constant_type(“proton mass”, 1.67262192595e-27_dp, 0.00000000052e-27_dp, “kg”): proton mass
PROTON_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent”, 1.50327761802e-10_dp, 0.00000000047e-10_dp, “J”): proton mass energy equivalent
PROTON_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“proton mass energy equivalent in MeV”, 938.27208943_dp, 0.00000029_dp, “MeV”): proton mass energy equivalent in MeV
PROTON_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“proton mass in u”, 1.0072764665789_dp, 0.0000000000083_dp, “u”): proton mass in u
PROTON_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“proton molar mass”, 1.00727646764e-3_dp, 0.00000000031e-3_dp, “kg mol^-1”): proton molar mass
PROTON_MUON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton-muon mass ratio”, 8.88024338_dp, 0.00000020_dp, “”): proton-muon mass ratio
PROTON_NEUTRON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mag. mom. ratio”, -1.45989802_dp, 0.00000034_dp, “”): proton-neutron mag. mom. ratio
PROTON_NEUTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton-neutron mass ratio”, 0.99862347797_dp, 0.00000000040_dp, “”): proton-neutron mass ratio
PROTON_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“proton relative atomic mass”, 1.0072764665789_dp, 0.0000000000083_dp, “”): proton relative atomic mass
PROTON_RMS_CHARGE_RADIUS: type(codata_constant_type), parameter = codata_constant_type(“proton rms charge radius”, 8.4075e-16_dp, 0.0064e-16_dp, “m”): proton rms charge radius
PROTON_TAU_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“proton-tau mass ratio”, 0.528051_dp, 0.000036_dp, “”): proton-tau mass ratio
QUANTUM_OF_CIRCULATION: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation”, 3.6369475467e-4_dp, 0.0000000011e-4_dp, “m^2 s^-1”): quantum of circulation
QUANTUM_OF_CIRCULATION_TIMES_2: type(codata_constant_type), parameter = codata_constant_type(“quantum of circulation times 2”, 7.2738950934e-4_dp, 0.0000000023e-4_dp, “m^2 s^-1”): quantum of circulation times 2
REDUCED_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“reduced Compton wavelength”, 3.8615926744e-13_dp, 0.0000000012e-13_dp, “m”): reduced Compton wavelength
REDUCED_MUON_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“reduced muon Compton wavelength”, 1.867594306e-15_dp, 0.000000042e-15_dp, “m”): reduced muon Compton wavelength
REDUCED_NEUTRON_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“reduced neutron Compton wavelength”, 2.1001941520e-16_dp, 0.0000000011e-16_dp, “m”): reduced neutron Compton wavelength
REDUCED_PLANCK_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“reduced Planck constant”, 1.054571817e-34_dp, 0.0_dp, “J s”): reduced Planck constant
REDUCED_PLANCK_CONSTANT_IN_EV_S: type(codata_constant_type), parameter = codata_constant_type(“reduced Planck constant in eV s”, 6.582119569e-16_dp, 0.0_dp, “eV s”): reduced Planck constant in eV s
REDUCED_PLANCK_CONSTANT_TIMES_C_IN_MEV_FM: type(codata_constant_type), parameter = codata_constant_type(“reduced Planck constant times c in MeV fm”, 197.3269804_dp, 0.0_dp, “MeV fm”): reduced Planck constant times c in MeV fm
REDUCED_PROTON_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“reduced proton Compton wavelength”, 2.10308910051e-16_dp, 0.00000000066e-16_dp, “m”): reduced proton Compton wavelength
REDUCED_TAU_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“reduced tau Compton wavelength”, 1.110538e-16_dp, 0.000075e-16_dp, “m”): reduced tau Compton wavelength
RYDBERG_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant”, 10973731.568157_dp, 0.000012_dp, “m^-1”): Rydberg constant
RYDBERG_CONSTANT_TIMES_C_IN_HZ: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times c in Hz”, 3.2898419602500e15_dp, 0.0000000000036e15_dp, “Hz”): Rydberg constant times c in Hz
RYDBERG_CONSTANT_TIMES_HC_IN_EV: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in eV”, 13.605693122990_dp, 0.000000000015_dp, “eV”): Rydberg constant times hc in eV
RYDBERG_CONSTANT_TIMES_HC_IN_J: type(codata_constant_type), parameter = codata_constant_type(“Rydberg constant times hc in J”, 2.1798723611030e-18_dp, 0.0000000000024e-18_dp, “J”): Rydberg constant times hc in J
SACKUR_TETRODE_CONSTANT_1_K_100_KPA: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 100 kPa)”, -1.15170753496_dp, 0.00000000047_dp, “”): Sackur-Tetrode constant (1 K, 100 kPa)
SACKUR_TETRODE_CONSTANT_1_K_101_325_KPA: type(codata_constant_type), parameter = codata_constant_type(“Sackur-Tetrode constant (1 K, 101.325 kPa)”, -1.16487052149_dp, 0.00000000047_dp, “”): Sackur-Tetrode constant (1 K, 101.325 kPa)
SECOND_RADIATION_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“second radiation constant”, 1.438776877e-2_dp, 0.0_dp, “m K”): second radiation constant
SHIELDED_HELION_GYROMAG_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio”, 2.0378946078e8_dp, 0.0000000018e8_dp, “s^-1 T^-1”): shielded helion gyromag. ratio
SHIELDED_HELION_GYROMAG_RATIO_IN_MHZ_T: type(codata_constant_type), parameter = codata_constant_type(“shielded helion gyromag. ratio in MHz/T”, 32.434100033_dp, 0.000000028_dp, “MHz T^-1”): shielded helion gyromag. ratio in MHz/T
SHIELDED_HELION_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom.”, -1.07455311035e-26_dp, 0.00000000093e-26_dp, “J T^-1”): shielded helion mag. mom.
SHIELDED_HELION_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to Bohr magneton ratio”, -1.15867149457e-3_dp, 0.00000000094e-3_dp, “”): shielded helion mag. mom. to Bohr magneton ratio
SHIELDED_HELION_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded helion mag. mom. to nuclear magneton ratio”, -2.1274977624_dp, 0.0000000017_dp, “”): shielded helion mag. mom. to nuclear magneton ratio
SHIELDED_HELION_TO_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to proton mag. mom. ratio”, -0.76176657721_dp, 0.00000000066_dp, “”): shielded helion to proton mag. mom. ratio
SHIELDED_HELION_TO_SHIELDED_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded helion to shielded proton mag. mom. ratio”, -0.7617861334_dp, 0.0000000031_dp, “”): shielded helion to shielded proton mag. mom. ratio
SHIELDED_PROTON_GYROMAG_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio”, 2.675153194e8_dp, 0.000000011e8_dp, “s^-1 T^-1”): shielded proton gyromag. ratio
SHIELDED_PROTON_GYROMAG_RATIO_IN_MHZ_T: type(codata_constant_type), parameter = codata_constant_type(“shielded proton gyromag. ratio in MHz/T”, 42.57638543_dp, 0.00000017_dp, “MHz T^-1”): shielded proton gyromag. ratio in MHz/T
SHIELDED_PROTON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom.”, 1.4105705830e-26_dp, 0.0000000058e-26_dp, “J T^-1”): shielded proton mag. mom.
SHIELDED_PROTON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to Bohr magneton ratio”, 1.5209931551e-3_dp, 0.0000000062e-3_dp, “”): shielded proton mag. mom. to Bohr magneton ratio
SHIELDED_PROTON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“shielded proton mag. mom. to nuclear magneton ratio”, 2.792775648_dp, 0.000000011_dp, “”): shielded proton mag. mom. to nuclear magneton ratio
SHIELDING_DIFFERENCE_OF_D_AND_P_IN_HD: type(codata_constant_type), parameter = codata_constant_type(“shielding difference of d and p in HD”, 1.98770e-8_dp, 0.00010e-8_dp, “”): shielding difference of d and p in HD
SHIELDING_DIFFERENCE_OF_T_AND_P_IN_HT: type(codata_constant_type), parameter = codata_constant_type(“shielding difference of t and p in HT”, 2.39450e-8_dp, 0.00020e-8_dp, “”): shielding difference of t and p in HT
SPEED_OF_LIGHT_IN_VACUUM: type(codata_constant_type), parameter = codata_constant_type(“speed of light in vacuum”, 299792458_dp, 0.0_dp, “m s^-1”): speed of light in vacuum
STANDARD_ACCELERATION_OF_GRAVITY: type(codata_constant_type), parameter = codata_constant_type(“standard acceleration of gravity”, 9.80665_dp, 0.0_dp, “m s^-2”): standard acceleration of gravity
STANDARD_ATMOSPHERE: type(codata_constant_type), parameter = codata_constant_type(“standard atmosphere”, 101325_dp, 0.0_dp, “Pa”): standard atmosphere
STANDARD_STATE_PRESSURE: type(codata_constant_type), parameter = codata_constant_type(“standard-state pressure”, 100000_dp, 0.0_dp, “Pa”): standard-state pressure
STEFAN_BOLTZMANN_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Stefan-Boltzmann constant”, 5.670374419e-8_dp, 0.0_dp, “W m^-2 K^-4”): Stefan-Boltzmann constant
TAU_COMPTON_WAVELENGTH: type(codata_constant_type), parameter = codata_constant_type(“tau Compton wavelength”, 6.97771e-16_dp, 0.00047e-16_dp, “m”): tau Compton wavelength
TAU_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“tau-electron mass ratio”, 3477.23_dp, 0.23_dp, “”): tau-electron mass ratio
TAU_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“tau energy equivalent”, 1776.86_dp, 0.12_dp, “MeV”): tau energy equivalent
TAU_MASS: type(codata_constant_type), parameter = codata_constant_type(“tau mass”, 3.16754e-27_dp, 0.00021e-27_dp, “kg”): tau mass
TAU_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“tau mass energy equivalent”, 2.84684e-10_dp, 0.00019e-10_dp, “J”): tau mass energy equivalent
TAU_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“tau mass in u”, 1.90754_dp, 0.00013_dp, “u”): tau mass in u
TAU_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“tau molar mass”, 1.90754e-3_dp, 0.00013e-3_dp, “kg mol^-1”): tau molar mass
TAU_MUON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“tau-muon mass ratio”, 16.8170_dp, 0.0011_dp, “”): tau-muon mass ratio
TAU_NEUTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“tau-neutron mass ratio”, 1.89115_dp, 0.00013_dp, “”): tau-neutron mass ratio
TAU_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“tau-proton mass ratio”, 1.89376_dp, 0.00013_dp, “”): tau-proton mass ratio
THOMSON_CROSS_SECTION: type(codata_constant_type), parameter = codata_constant_type(“Thomson cross section”, 6.6524587051e-29_dp, 0.0000000062e-29_dp, “m^2”): Thomson cross section
TRITON_ELECTRON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“triton-electron mass ratio”, 5496.92153551_dp, 0.00000021_dp, “”): triton-electron mass ratio
TRITON_G_FACTOR: type(codata_constant_type), parameter = codata_constant_type(“triton g factor”, 5.957924930_dp, 0.000000012_dp, “”): triton g factor
TRITON_MAG_MOM: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom.”, 1.5046095178e-26_dp, 0.0000000030e-26_dp, “J T^-1”): triton mag. mom.
TRITON_MAG_MOM_TO_BOHR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to Bohr magneton ratio”, 1.6223936648e-3_dp, 0.0000000032e-3_dp, “”): triton mag. mom. to Bohr magneton ratio
TRITON_MAG_MOM_TO_NUCLEAR_MAGNETON_RATIO: type(codata_constant_type), parameter = codata_constant_type(“triton mag. mom. to nuclear magneton ratio”, 2.9789624650_dp, 0.0000000059_dp, “”): triton mag. mom. to nuclear magneton ratio
TRITON_MASS: type(codata_constant_type), parameter = codata_constant_type(“triton mass”, 5.0073567512e-27_dp, 0.0000000016e-27_dp, “kg”): triton mass
TRITON_MASS_ENERGY_EQUIVALENT: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent”, 4.5003878119e-10_dp, 0.0000000014e-10_dp, “J”): triton mass energy equivalent
TRITON_MASS_ENERGY_EQUIVALENT_IN_MEV: type(codata_constant_type), parameter = codata_constant_type(“triton mass energy equivalent in MeV”, 2808.92113668_dp, 0.00000088_dp, “MeV”): triton mass energy equivalent in MeV
TRITON_MASS_IN_U: type(codata_constant_type), parameter = codata_constant_type(“triton mass in u”, 3.01550071597_dp, 0.00000000010_dp, “u”): triton mass in u
TRITON_MOLAR_MASS: type(codata_constant_type), parameter = codata_constant_type(“triton molar mass”, 3.01550071913e-3_dp, 0.00000000094e-3_dp, “kg mol^-1”): triton molar mass
TRITON_PROTON_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“triton-proton mass ratio”, 2.99371703403_dp, 0.00000000010_dp, “”): triton-proton mass ratio
TRITON_RELATIVE_ATOMIC_MASS: type(codata_constant_type), parameter = codata_constant_type(“triton relative atomic mass”, 3.01550071597_dp, 0.00000000010_dp, “”): triton relative atomic mass
TRITON_TO_PROTON_MAG_MOM_RATIO: type(codata_constant_type), parameter = codata_constant_type(“triton to proton mag. mom. ratio”, 1.0666399189_dp, 0.0000000021_dp, “”): triton to proton mag. mom. ratio
UNIFIED_ATOMIC_MASS_UNIT: type(codata_constant_type), parameter = codata_constant_type(“unified atomic mass unit”, 1.66053906892e-27_dp, 0.00000000052e-27_dp, “kg”): unified atomic mass unit
VACUUM_ELECTRIC_PERMITTIVITY: type(codata_constant_type), parameter = codata_constant_type(“vacuum electric permittivity”, 8.8541878188e-12_dp, 0.0000000014e-12_dp, “F m^-1”): vacuum electric permittivity
VACUUM_MAG_PERMEABILITY: type(codata_constant_type), parameter = codata_constant_type(“vacuum mag. permeability”, 1.25663706127e-6_dp, 0.00000000020e-6_dp, “N A^-2”): vacuum mag. permeability
VON_KLITZING_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“von Klitzing constant”, 25812.80745_dp, 0.0_dp, “ohm”): von Klitzing constant
WEAK_MIXING_ANGLE: type(codata_constant_type), parameter = codata_constant_type(“weak mixing angle”, 0.22305_dp, 0.00023_dp, “”): weak mixing angle
WIEN_FREQUENCY_DISPLACEMENT_LAW_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Wien frequency displacement law constant”, 5.878925757e10_dp, 0.0_dp, “Hz K^-1”): Wien frequency displacement law constant
WIEN_WAVELENGTH_DISPLACEMENT_LAW_CONSTANT: type(codata_constant_type), parameter = codata_constant_type(“Wien wavelength displacement law constant”, 2.897771955e-3_dp, 0.0_dp, “m K”): Wien wavelength displacement law constant
W_TO_Z_MASS_RATIO: type(codata_constant_type), parameter = codata_constant_type(“W to Z mass ratio”, 0.88145_dp, 0.00013_dp, “”): W to Z mass ratio

\(\)

Fortran#

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