Table 7.6 -- EUs whose label begins with M-Z
Label | Symbol | Quantity | Definition | EQ label | Code | References |
METRE | m | (instantaneous) sound particle displacement | Instantaneous displacement of a particle in a medium from what would be its position in the absence of sound waves. | LENGTH | 142 | [I31-7, 7-10.a] |
Bohr radius | The radius of the electron orbit having the lowest energy in the Bohr atom; 0,5292 x 10-10 m. | [I31-9, 9-8.a] | ||||
Burgers vector | The vector characterizing a dislocation, i.e. the closing vector in a Burgers circuit encircling a dislocation line. | [I31-13, 13-7.a] | ||||
coherence length | The distance in a superconductor over which the effect of a perturbation is appreciable. | [I31-13, 13-39.a] | ||||
Compton wavelength | The wavelength associated with the mass of any particle. | [I31-9, 9-27.a] | ||||
diffusion length | The square root of the diffusion area. | [I31-10, 10-41.a] | ||||
diffusion length | The mean distance that a particle travels before it is absorbed or recombines. | [I31-13, 13-34.a] | ||||
electron radius | The classical theoretical radius of an electron, 2,82 x 10-15 m, obtained by equating the rest mass energy of an electron to the coulomb energy. | [I31-9, 9-26.a] | ||||
focal distance | For a single thin lens, the distance from the centre of the lens to the focal point. | [I31-6, 6-45.a] | ||||
fundamental lattice vector | The fundamental translation vectors for the crystal lattice. | [I31-13, 13-1.a] | ||||
half-thickness (half-value thickness) | The thickness of the attenuating layer that reduces the current density of a unidirectional beam to one-half of its initial value. | [I31-10, 10-17.a] | ||||
lattice plane spacing | The distance between successive lattice planes. | [I31-13, 13-3.a] | ||||
lattice vector | The translation vector which maps the crystal lattice on itself. | [I31-13, 13-1.a] | ||||
length | The length of the path travelled by light in vacuum during a time interval of 1 / 299 792 458 of a second. SI base unit. |
[I31-0, Table 1], [I31-1, 1-3.a] |
||||
mean free path | The average distance that particles travel between two successive specified reactions or processes. | [I31-10, 10-39.a] | ||||
mean free path | For a molecule, the average distance between two successive collisions. | [I31-8, 8-38.a] | ||||
mean free path | The average distance traveled by a particle between collisions with another particle in the system. | [I31-13, 13-16.a] | ||||
mean linear range | The distance that a particle penetrates in a given substance under specified conditions averaged over a group of particles having the same initial energy. | [I31-10, 10-21.a] | ||||
migration length | The square root of the migration area. | [I31-10, 10-41.a] | ||||
nuclear radius | The average radius of the volume in which the nuclear matter is included. | [I31-9, 9-17.a] | ||||
slowing-down length | The square root of the slowing-down area. | [I31-10, 10-41.a] | ||||
wavelength | The distance in the direction of propagation of a periodic wave between two successive points where at a given time the phase is the same. | [I31-2, 2-5.a], [I31-6, 6-3.a], [I31-7, 7-5.a] |
||||
METRE_FOURTH_POWER | m4 | second moment of area (second axial moment of area) | The second axial moment of area of a plane area (section) about an axis in its plane is the sum (integral) of the products of its elements of area and the squares of their distances from the axis or point. | SECOND_MOMENT_AREA | 143 | [I31-3, 3-20.a] |
METRE_KELVIN | m · K | second radiation constant | The constant c2 in the expression for the spectral concentration of the radiant exitance of a full radiator (black body). | SECOND_RADIATION- _CONSTANT |
144 | [I31-6, 6-20.a] |
METRE_PER_HOUR | m/h | velocity | The distance divided by time. 1 m/h = 1 / 3,6 x 10-3 m/s (exactly). |
SPEED | 145 | [I31-1, 1-10.a, I31-0, 2.3.2.3] |
METRE_PER_SEC | m/s | group velocity | The velocity of a packet of waves having different frequencies and phase velocities. | SPEED | 146 | [I31-2, 2-8.a] |
neutron speed | The magnitude of the neutron velocity. | [I31-10, 10-30.a] | ||||
phase velocity | In wave propagation, the velocity of a surface of constant phase; this would be the speed of the wave. | [I31-2, 2-8.a] | ||||
velocity | The distance divided by time. | [I31-1, 1-10.a] | ||||
METRE_PER_SEC_SQD | m/s2 | acceleration | The change in velocity divided by time. | ACCELERATION | 147 | [I31-1, 1-11.a], [I31-7, 7-12.a] |
MINUTE | min | time | 1 min = 60 s (exactly). | TIME | 150 | [I31-0, Table 4], [I31-1, 1-7.b] |
MINUTE_ARC | ' | plane angle | The angle between two half-lines terminating at the same point is defined as the ratio of the length of the included arc of the circle (with its centre at that point) to the radius of that circle. 1' = (1 / 60)º = (π / 10 800) rad (exactly). |
PLANE_ANGLE | 151 | [I31-0, Table 4], [I31-1, 1-1.c] |
MINUTE_PER_CUBIC_METRE | min/m3 | volumetric entity dose (any elementary entity: atoms, molecules, ions, electrons, other particles, or specified groups of such particles) | The time integral of exposure to a number of molecules or particles divided by their volume. 1 min/3 = 60 s/m3 (exactly). |
VOLUMIC_DOSE | 152 | [I31-8, 8-10.a, I31-0, 2.3.2.2 (derived)] |
MOLE | mol | amount of substance | The amount of substance in a system which contains as many elementary entities as there are atoms in 0,012 kilogram of carbon 12. When the mole is used, the elementary entities must be specified, and may be atoms, molecules, ions, electrons, other particles, or specified groups of such particles. SI base unit. |
AMOUNT_SUBSTANCE | 153 | [I31-0, Table 1], [I31-8, 8-3.a] |
MOLE_PER_CUBIC_M | mol/m3 | concentration (amount-of-substance concentration) | The amount of substance divided by the volume of the mixture. | CONCENTRATION | 154 | [I31-8, 8-13.a] |
MOLE_PER_KG | mol/kg | ionic strength | The mass concentration of ions in a solution. | MOLALITY_SOLUTE | 155 | [I31-8, 8-46.a] |
molality of solute | The amount of substance of solute in a solution divided by the mass of the solvent. | [I31-8, 8-16.a] | ||||
MOLE_PER_LITRE | mol/l, mol/L | concentration (amount-of-substance concentration) | The amount of substance divided by the volume of the mixture. 1 mol/l = 103 mol/m3 (exactly). |
CONCENTRATION | 156 | [I31-8, 8-13.b] |
MOLE_PER_MOLE | mol/mol | mole fraction (of B) | The ratio of the amount of substance of B to the amount of substance of the mixture. 1 mol/mol = 1. |
MOLE_FRACTION | 157 | [I31-8, 8-14.a], [I31-0, 2.3.3] |
NEPER | Np | field quantity ratio (level difference) | Twice the natural logarithm of a field quantity ratio. 1 Np is the level of a field quantity when ln (F/F0) = 1 where F and F0 represent two amplitudes of the same kind, F0 being a reference amplitude. |
FIELD_OR_POWER- _LEVEL_DIFF |
159 | [I31-2, 2-9.a] |
logarithmic decrement | The product of damping coefficient and period. | [I31-2, 2-12.a], [I31-7, 7-25.a] |
||||
power quantity ratio (level difference) | The natural logarithm of a power quantity ratio. 1 Np is the level of a power quantity when 1/2 ln (P/P0) = 1 where P and P0 represent two powers of the same kind, P0 being a reference power. |
[I31-2, 2-10.a] | ||||
NEPER_PER_SECOND | Np/s | damping coefficient | The factor defining the rate of exponential amplitude decay in a periodic or acoustic system. | DAMPING_COEFFICIENT | 160 | [I31-2, 2-11.b], [I31-7, 7-23.b] |
NEWTON | N | force | An external agent that causes a change in the motion of a free body, or that causes stress in a fixed body; proportional to the rate of change in momentum. 1 N = 1 (m · kg)/s2. |
FORCE | 161 | [I31-0, Table 2], [I31-3, 3-9.a] |
NEWTON_M_SQD_PER_KG_SQD | (N · m2)/kg2 | gravitational force between two particles | The force of attraction between massive bodies due to gravitation. 1 N · m2/kg2 = 1 m3/(kg · s2). |
GRAVITATIONAL_FORCE | 162 | [I31-3, 3-14.a] |
NEWTON_METRE | N · m | moment of force | Torque, the tendency of a force to cause an object to rotate about a given point. 1 N · m = 1 (m2 · kg2)/s2. |
MOMENT_FORCE | 163 | [I31-3, 3-12.a] |
NEWTON_METRE_SECOND | N · m · s | angular impulse | The integral over time of all torques applied. 1 N · m · s = 1 (m2 · kg2)/s. |
ANGULAR_IMPULSE | 164 | [I31-3, 3-13.a] |
NEWTON_PER_METRE | N/m | surface tension | The stretching force required to form a liquid film, tending to minimize the area of a surface; equal to the surface energy of the liquid per unit length of the film at equilibrium. 1 N/m = 1 kg/s2. |
SURFACE_TENSION | 165 | [I31-3, 3-25.a] |
NEWTON_PER_SQ_M | N/m2 | fugacity (in a gaseous mixture) | A function substituting for pressure, allowing a real gas system to be considered by the same equations that apply to an ideal gas. | PRESSURE | 166 | [I31-8, 8-20.a] |
instantaneous sound pressure | The difference between the instantaneous total pressure and the static pressure. | [I31-7, 7-9.a] | ||||
modulus of elasticity | The stress per unit elastic strain, expressed as a ratio between the stress placed on a material and the strain, or dimensional response to stress. | [I31-3, 3-18.a] | ||||
osmotic pressure | The excess pressure required to maintain osmotic equilibrium between a solution and the pure solvent separated by a membrane permeable only to the solvent. | [I31-8, 8-26.a] | ||||
partial pressure (of B, in a gaseous mixture) | For a gaseous mixture, pB = xB·p, where p is the pressure. | [I31-8, 8-19.a] | ||||
pressure | The force that is exerted per unit area. 1 N/m2 = 1 Pa = 1 kg/(m · s2). |
[I31-0, Table 2] | ||||
pressure | The force divided by the area over which it is applied. | [I31-3, 3-15.a] | ||||
static pressure | The pressure that would exist in the absence of sound waves. | [I31-7, 7-9.a] | ||||
NEWTON_SECOND | N · s | impulse | A vector quantity given by the integral over time of the force acting on a body, usually in a collision in which the time interval is very brief; it is equal to the change in the momentum of the body. 1 N · s = 1 (m · kg)/s. |
IMPULSE | 167 | [I31-3, 3-10.a] |
NEWTON_SECOND_PER_METRE | (N · s)/m | mechanical impedance | At a surface (or at a point), the complex representation of total force divided by the complex representation of average particle velocity at that surface (or of particle velocity at that point) in the direction of the force. 1 (N · s)/m = 1 kg/s. |
MECHANICAL_IMPEDANCE | 168 | [I31-7, 7-19.a] |
OCTAVE | none | frequency interval | The numerical value of a frequency interval in octaves is given by lb (f2/f1), when f2 is greater than f1. | FREQUENCY_INTERVAL | 169 | [I31-7, 7-3.a] |
OHM | Ω | electrical resistance | The electric potential difference divided by current when there is no electromotive force in the conductor. 1 Ω = 1 V/A = 1 (m2 · kg)/(s3 · A2). |
RESISTANCE | 170 | [I31-0, Table 2], [I31-5, 5-33.a], [I31-5, 5-44.a] |
OHM_METRE | Ω · m | residual resistivity | For metals, the resistivity extrapolated to zero thermodynamic temperature. | RESISTIVITY | 171 | [I31-13, 13-18.a] |
resistivity | The inherent ability of a material to resist current flow. 1 Ω · m = 1 (m3 · kg)/(s3 · A2). |
[I31-5, 5-36.a] | ||||
PASCAL | Pa | fugacity (in a gaseous mixture) | A function substituting for pressure, allowing a real gas system to be considered by the same equations that apply to an ideal gas. | PRESSURE | 173 | [I31-8, 8-20.a] |
instantaneous sound pressure | Difference between the instantaneous total pressure and the static pressure. | [I31-7, 7-9.a] | ||||
modulus of elasticity | The stress per unit elastic strain, expressed as a ratio between the stress placed on a material and the strain, or dimensional response to stress. | [I31-7, 7-9.a] | ||||
osmotic pressure | The excess pressure required to maintain osmotic equilibrium between a solution and the pure solvent separated by a membrane permeable only to the solvent. | [I31-8, 8-26.a] | ||||
partial pressure (of B, in a gaseous mixture) | For a gaseous mixture, pB = xB·p, where p is the pressure. | [I31-8, 8-19.a] | ||||
pressure | The force that is exerted per unit area. 1 Pa = 1 N/m2 = 1 kg/(m · s2). |
[I31-0, Table 2], [I31-3, 3-15.a] |
||||
pressure | The force divided by the area over which it is applied. | [I31-3, 3-18.a] | ||||
static pressure | The pressure that would exist in the absence of sound waves. | [I31-7, 7-9.a] | ||||
PASCAL_PER_KELVIN | Pa/K | pressure coefficient | The fractional change in the pressure of a gas sample divided by the fractional change in the temperature under specified conditions, such as constant volume. 1 Pa/K = 1 kg/(m · s2 · K). |
PRESSURE_COEFFICIENT | 174 | [I31-4, 4-4.a] |
PASCAL_PER_SEC | Pa/s | pressure change rate | The rate of change in force is exerted per unit area. 1 Pa/s = 1 kg/(m · s3). |
PRESSURE_CHANGE_RATE | 175 | [I31-0, 2.3.2.2 (derived)] |
PASCAL_SEC | Pa · s | dynamic viscosity | The constant of proportionality of the rate of deformation of a Newtonian fluid, directly proportional to the applied shear stress. 1 Pa · s = 1 kg/(m · s). |
DYNAMIC_VISCOSITY | 176 | [I31-3, 3-23.a] |
PASCAL_SEC_PER_CUBIC_METRE | (Pa · s)/m3 | acoustic impedance | At a surface, the complex representation of sound pressure divided by the complex representation of volume flow rate. 1 (Pa · s)/m3 = 1 kg/(m4 · s). |
ACOUSTIC_IMPEDANCE | 177 | [I31-7, 7-18.a] |
PASCAL_SEC_PER_METRE | (Pa · s)/m | characteristic impedance of a medium | At a point in a medium and for a plane progressive wave, the complex representation of sound pressure divided by the complex representation of particle velocity. 1 (Pa · s)/m = 1 kg/(m2 · s). |
SURFACE_DENSITY- _MECH_IMPED |
178 | [I31-7, 7-20.a] |
PHON | none | loudness level | 1 phon is the loudness level when 2 lb (peff/p0)1 kHz = 0,1 , where peff is the root-mean-square value of the sound pressure of a pure tone of 1 kHz, which is judged by a normal observer under standardized listening conditions as being as loud as the sound under investigation, and where p0 = 20 μPa. | LOUDNESS_LEVEL | 180 | [I31-7, 7-31.a] |
RADIAN | rad | angle of optical rotation | Angle through which plane-polarized light is rotated clockwise, as seen when facing the light source, in passing through an optically active medium. | PLANE_ANGLE | 186 | [I31-8, 8-51.a] |
phase difference | The relative angular displacement between a periodic quantity and a reference angle or between two sinusoidally varying quantities of identical frequencies. | [I31-5, 5-43.a] | ||||
plane angle | The angle between two half-lines terminating at the same point is defined as the ratio of the length of the included arc of the circle (with its centre at that point) to the radius of that circle. 1 rad = 1 m/m = 1 A complete angle (full circle) is 2π rad. |
[I31-0, Table 2], [I31-1, 1-1.a] |
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RADIAN_PER_METRE | rad/m | angular repetency (angular wave number) | The reciprocal of the wavelength or the number of waves per unit angle along the direction of propagation. | ANGULAR_REPETENCY | 187 | [I31-2, 2-7.a], [I31-6, 6-5.a], [I31-7, 7-7.a], [I31-13, 13-10.a] |
RADIAN_PER_SEC | rad/s | angular frequency | The frequency of rotation or vibration. | ANGULAR_VELOCITY | 188 | [I31-2, 2-4.a], [I31-5, 5-42.a], [I31-7, 7-4.a] |
angular frequency | The number of cycles or revolutions divided by time. | [I31-6, 6-2.a], [I31-9, 9-14.a], [I31-9, 9-15.a], [I31-13, 13-11.a] |
||||
angular velocity | The change in angular position divided by time. | [I31-1, 1-8.a] | ||||
pulsatance | The angular velocity of a periodic quantity. | [I31-2, 2-4.a], [I31-5, 5-42.a], [I31-7, 7-4.a] |
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RADIAN_PER_SEC_SQD | rad/s2 | angular acceleration | The change in angular velocity divided by time. | ANGULAR_ACCELERATION | 189 | [I31-1, 1-9.a] |
SECOND | s | carrier life time | The time constant for recombination or trapping of minority charge carriers in semiconductors. | TIME | 192 | [I31-13, 13-33.a] |
half-life | The average time required for the decay of one half of the atoms of a sample of a radioactive nuclide. | [I31-9, 9-37.a] | ||||
mean life | The average amount of time an unstable radioisotope exists before it decays, equal to the reciprocal of the decay constant. | [I31-9, 9-31.a] | ||||
period (periodic time) | The time of one cycle. | [I31-2, 2-1.a], [I31-7, 7-1.a] |
||||
reactor time constant | The time required for the neutron fluence rate in a reactor to change by the factor e when the fluence rate is rising or falling exponentially. | [I31-10, 10-48.a] | ||||
relaxation time | The time constant for exponential decay towards equilibrium. | [I31-13, 13-33.a] | ||||
reverberation time | The time required for the average sound energy density in an enclosure to decrease to 10-6 of its initial value (i.e., by 60 dB) after the source has stopped. | [I31-7, 7-30.a] | ||||
time | The duration of 9 192 631 770 periods of the radiation corresponding to the transition between two hyperfine levels of the ground state of the caesium-133 atom. SI base unit. |
[I31-0, Table 1], [I31-1, 1-7.a] |
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time constant (relaxation time) | The reciprocal of the damping coefficient. | [I31-7, 7-24.a] | ||||
time constant of an exponentially varying quantity | The time after which the quantity would reach its limit if it maintained its initial rate of variation. | [I31-2, 2-2.a] | ||||
SECOND_ARC | " | plane angle | The angle between two half-lines terminating at the same point is defined as the ratio of the length of the included arc of the circle (with its centre at that point) to the radius of that circle. 1" = (1 / 3 600)º = (π / 648 000) rad (exactly). |
PLANE_ANGLE | 193 | [I31-0, Table 4], [I31-1, 1-1.d] |
SECOND_PER_CUBIC_M_RADIAN | s/(m3 · rad) | spectral concentration of vibrational modes (in terms of angular frequency) | The number of vibrational modes in an infinitesimal interval of angular frequency, divided by the size of that interval and by volume. 1 s/(m3 · rad) = 1 s/m3 (exactly). |
SPECTRAL_CONC- _VIBRAT_MODES |
194 | [I31-13, 13-13.a] |
SECOND_PER_CUBIC_METRE | s/m3 | volumetric entity dose (any elementary entity: atoms, molecules, ions, electrons, other particles, or specified groups of such particles) | The time integral of exposure to a number of molecules or particles divided by their volume. | VOLUMIC_DOSE | 195 | [I31-8, 8-10.a, I31-0, 2.3.2.2 (derived)] |
SIEMENS | S | admittance | The reciprocal of the complex representation of potential difference divided by the complex representation of current; the reciprocal of impedance. | ELECTRIC_CONDUCTANCE | 196 | [I31-5, 5-45.a] |
electrical conductance | The electric current divided by potential difference when there is no electromotive force in the conductor; the reciprocal of electrical resistance. 1 S = 1 Ω-1 = 1 (s3 · A2)/(m2 · kg). |
[I31-0, Table 2], [I31-5, 5-34.a] |
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SIEMENS_M_SQD_PER_MOLE | (S · m2)/mol | molar conductivity | The conductivity divided by the amount-of-substance concentration. 1 (S · m2)/mol = 1 (s3 · A2)/(kg · mol). |
MOLAR_CONDUCTIVITY | 197 | [I31-8, 8-49.a] |
SIEMENS_PER_METRE | S/m | electrical conductivity | The electric current density divided by the electric field strength. 1 S/m = 1 (s3 · A2)/(m3 · kg). |
ELECTRIC- _CONDUCTIVITY |
198 | [I31-5, 5-37.a] |
electrolytic conductivity | The electrolytic current density divided by the electric field strength. | [I31-8, 8-48.a] | ||||
SIEVERT | Sv | dose equivalent of ionizing radiation | The product of D, Q and N, at the point of interest in tissue, where D is the absorbed dose, Q is the quality factor and N is the product of any other modifying factors. 1 Sv = 1 J/kg = 1 m2/s2. |
DOSE_EQUIVALENT | 199 | [I31-0, Table 3], [I31-10, 10-52.a] |
SONE | none | loudness | A normal observer's auditory estimate of the ratio between the strength of the sound considered and that of a reference sound having a loudness level of 40 phons. | LOUDNESS | 200 | [I31-7, 7-32.a] |
SQ_METRE | m2 | area | The product of length and width. | AREA | 201 | [I31-1, 1-5.a], [I31-7, 7-29.a], [I31-9, 9-16.a], [I31-10, 10-3.a], [I31-10, 10-16.a], [I31-10, 10-40.a] |
SQ_METRE_AMP_PER_JOULE_SEC | (m2 · A)/(J · s) | gyromagnetic coefficient (gyromagnetic ratio) | The ratio of the magnetic moment to the intrinsic angular momentum of a spinning particle. 1 (m2 · A)/(J · s) = 1 (s · A)/kg. |
GYROMAGNETIC- _COEFFICIENT |
202 | [I31-9, 9-12.a] |
SQ_METRE_AMPERE | m2 · A | magnetic moment (electromagnetic moment) | A vector quantity, the vector product of which with the magnetic flux density of a homogeneous field is equal to the torque. | MAGNETIC_MOMENT | 203 | [I31-5, 5-27.a] |
magnetic moment of particle or nucleus | Expectation value of the component of the electromagnetic moment in the direction of the magnetic field in the quantum state with maximum magnetic quantum number. | [I31-9, 9-11.a] | ||||
SQ_METRE_KELVIN_PER_WATT | (m2 · K)/W | thermal insulance (coefficient of thermal insulation) | The temperature difference divided by areic heat flow rate. 1 (m2 · K)/W = 1 (s3 · K)/kg. |
THERMAL_INSULANCE | 204 | [I31-4, 4-11.a] |
SQ_METRE_PER_JOULE | m2/J | spectral cross-section | Cross-section for a process in which the energy of the ejected or scattered particle is in an element of energy, divided by this element. 1 m2/J = 1 s2/kg. |
SPECTRAL_CROSS- _SECTION |
205 | [I31-10, 10-5.a] |
SQ_METRE_PER_JOULE_SR | m2/(J · sr) | spectral angular cross-section | Cross-section for ejecting or scattering a particle into an element of solid angle with energy in an element of energy, divided by the product of these two elements. 1 m2/(J · sr) = 1 s2/(kg · sr). |
SPECTRAL_ANGULAR- _CROSS_SECT |
206 | [I31-10, 10-6.a] |
SQ_METRE_PER_KG | m2/kg | mass attenuation coefficient | The linear attenuation coefficient divided by the volumic mass of the substance. | MASS_ATTENUATION- _COEFF |
207 | [I31-10, 10-14.a] |
SQ_METRE_PER_MOLE | m2/mol | molar absorption coefficient | The linear attenuation coefficient divided by the volumic amount of the substance. | MOLAR_ABSORPTION- _COEFF |
208 | [I31-6, 6-43.a] |
molar attenuation coefficient | The linear attenuation coefficient divided by the amount-of-substance concentration. | [I31-10, 10-15.a] | ||||
SQ_METRE_PER_SECOND | m2/s | diffusion coefficient | The rate at which atoms or ions diffuse across a surface area per unit time. | KINEMATIC_VISCOSITY | 209 | [I31-8, 8-39.a], [I31-10, 10-32.a] |
kinematic viscosity | The absolute viscosity of a fluid divided by its density. | [I31-3, 3-24.a] | ||||
thermal diffusivity | The ratio of thermal conductivity to the heat capacity per unit volume for a material. | [I31-4, 4-14.a] | ||||
SQ_METRE_PER_STERADIAN | m2/sr | angular cross-section | The cross-section for ejecting or scattering a particle into an element of solid angle, divided by this element. | ANGULAR_CROSS- _SECTION |
210 | [I31-10, 10-4.a] |
SQ_METRE_PER_VOLT_SECOND | m2/(V · s) | mobility | The average drift velocity imparted to a charged particle in a medium by an electric field, divided by the field strength. 1 m2/(V · s) = 1 (s2 · A)/kg. |
MOBILITY | 211 | [I31-10, 10-26.a] |
SQ_METRE_RADIAN_PER_KG | (m2 · rad)/kg | massic optical rotatory power (specific optical rotatory power) | The cross-sectional area of a linearly polarized light beam times its angle of optical rotation, divided by the mass of the optically active component in the path. | MASSIC_OPTICAL_ROT- _POWER |
212 | [I31-8, 8-53.a] |
SQ_METRE_RADIAN_PER_MOLE | (m2 · rad)/mol | molar optical rotatory power | The cross-sectional area of a linearly polarized light beam times its angle of optical rotation, divided by the amount of substance of the optically active component in the path. | MOLAR_OPTICAL_ROT- _POWER |
213 | [I31-8, 8-52.a] |
STERADIAN | sr | solid angle | The solid angle of a cone is defined as the ratio of the area cut out on a spherical surface (with its centre at the apex of that cone) to the square of the radius of the sphere. 1 sr = 1 m2/m2 = 1 A complete angle over all space (full sphere) is 4π sr. |
SOLID_ANGLE | 214 | [I31-0, Table 2], [I31-1, 1-2.a] |
TEC | none | total electron count (areal electron density) | At a given point in space, the number of electrons incident on a small sphere, divided by the cross-sectional area of that sphere. 1 TEC = 1016 1/m2 (exactly). |
AREAL_ENTITY_DENSITY | 215 | [I31-6, 6-28.a] |
TESLA | T | magnetic flux density (magnetic induction) | The amount of magnetic flux through a unit area taken perpendicular to the direction of the magnetic flux. 1 T = 1 Wb/m2 = 1 kg/(s2 · A). |
MAGNETIC_FLUX- _DENSITY |
216 | [I31-0, Table 2], [I31-5, 5-19.a] |
thermodynamic critical magnetic flux density | The critical flux density for disappearance of superconductivity in type I superconductors. | [I31-13, 13-37.a] | ||||
TONNE | t | mass | 1 t = 1 000 kg (exactly). | MASS | 218 | [I31-0, Table 4], [I31-3, 3-1.b] |
TONNE_PER_CUBIC_METRE | t/m3 | volumic mass (mass density) | The mass divided by the volume. 1 t/m3 = 103 kg/m3 (exactly). |
VOLUMIC_MASS | 219 | [I31-3, 3-2.b] |
UNIFIED_AMASS_UNIT | u | molecular mass | The value of the unified atomic mass unit is determined experimentally and is equal to (1 / 12) of the mass of an atom of the nuclide 12C; 1 u = 1,660 540 x 10-27 kg (approximately). | MASS | 220 | [I31-0, Table 6], [I31-8, 8-31.b], [I31-9, 9-4.b], [I31-9, 9-5.b], [I31-9, 9-28.b] |
UNITLESS | 1 (often omitted) | special (pure number) | 1. | PURE_NUMBER | 221 | [I31-0, 2.3.3] |
VOLT | V | electric potential | The potential measured by the energy of a unit positive charge at a point, expressed relative to an equipotential surface, generally the surface of the <EARTH>, that has zero potential. 1 V = 1 W/A = 1 (m2 · kg)/(s3 · A). |
ELECTRIC_POTENTIAL | 222 | [I31-0, Table 2], [I31-5, 5-6.a] |
electromotive force | The energy supplied by a source divided by the electric charge transported through the source. 1 V = 1 W/A = 1 (m2 · kg)/(s3 · A). |
[I31-0, Table 2], [I31-5, 5-6.a] |
||||
Peltier coefficient | The Peltier heat power developed at a junction, divided by the electric current flowing from substance A to substance B. | [I31-13, 13-23.a] | ||||
VOLT_AMP | V · A | apparent power | In electric power technology, active power is expressed in watts (W), apparent power in volt amperes (V · A) and reactive power in vars (var). 1 V · A = 1 (m2 · kg)/(s3 · A). |
APPARENT_POWER | 223 | [I31-5, 5-50.a], [I1000, Annex A 5-49] |
VOLT_PER_KELVIN | V/K | Seebeck coefficient | The thermoelectromotive force between two substances divided by the temperature of their hot junction. 1 V/K = 1 (m2 · kg)/(s3 · A · K). |
SEEBECK_COEFFICIENT | 224 | [I31-13, 13-22.a] |
Thomson coefficient | The Thomson heat power developed divided by the electric current and temperature difference. | [I31-13, 13-24.a] | ||||
VOLT_PER_METRE | V/m | electric field strength | The force, exerted by electric field on an electric point charge, divided by the electric charge. 1 V/m = 1 N/C = 1 (m · kg)/(s3 · A). |
ELECTRIC_FIELD- _STRENGTH |
225 | [I31-5, 5-5.a] |
VOLT_SQD_PER_KELVIN_SQD | V2/K2 | Lorenz coefficient | The thermal conductivity divided by the electrical conductivity and the thermodynamic temperature. 1 V2/K2 = 1 (m4 · kg2)/(s6 · A2 · K2). |
LORENZ_COEFFICIENT | 226 | [I31-13, 13-19.a] |
WATT | W | heat flow rate | The rate at which heat crosses a given surface. | POWER | 227 | [I31-4, 4-7.a] |
power | The rate of energy transfer. 1 W = 1 J/s = 1 (m2 · kg)/s3. |
[I31-0, Table 2], [I31-3, 3-27.a], [I31-5, 5-35.a] |
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radiant power (radiant energy flux) | The power emitted, transferred or received as radiation. | [I31-6, 6-10.a] | ||||
sound power | The power emitted, transferred or received as sound waves. | [I31-7, 7-16.a] | ||||
WATT_HOUR | W · h | electrical active energy | The practical unit of energy in electrical systems. 1 W · h = 3 600 J (exactly). |
ENERGY | 228 | [I31-5, 5-52.b] |
WATT_PER_KELVIN | W/K | thermal conductance | The heat flow rate divided by temperature difference; the reciprocal of thermal resistance. 1 W/K = 1 (m2 · kg)/(s3 · K). |
THERMAL_CONDUCTANCE | 229 | [I31-4, 4-13.a] |
WATT_PER_METRE_K | W/(m · K) | thermal conductivity | The areic heat flow rate divided by temperature gradient. 1 W/(m · K) = 1 (m · kg)/(s3 · K). |
THERMAL_CONDUCTIVITY | 230 | [I31-4, 4-9.a] |
WATT_PER_SQ_CM_SEC | W/(cm2 · s) | radiant exitance rate | At a point on a surface, the radiant energy flux leaving the element of the surface over an interval of time, divided by the area of that element and that time. 1 W/(cm2 · s) = 10-4 W/(m2 · s) (exactly). |
RADIANT_EXITANCE- _RATE |
231 | [I31-0, 2.3.2.3 (derived)] |
WATT_PER_SQ_M_HZ | W/(m2 · Hz) | flux density (frequency dependent) | The amount of a given type of radiation that crosses a specified area within a specified period. 1 W/(m2 · Hz) = 1 kg/s2. |
FLUX_DENSITY | 232 | [I31-0, 2.3.1 and 2.3.2 (derived)] |
WATT_PER_SQ_M_K_FOURTH_PWR | W/(m2 · K4) | Stefan-Boltzmann constant | The constant relating the power per unit area emitted by a radiating black body to its thermodynamic temperature. 1 W/(m2 · K4) = 1 kg/(s3 · K4). |
STEFAN_BOLTZMAN- _CONSTANT |
233 | [I31-6, 6-18.a] |
WATT_PER_SQ_METRE | W/m2 | areic heat flow rate (density of heat flow rate) | The heat flow rate divided by area. 1 W/m2 = 1 kg/s3. |
IRRADIANCE | 234 | [I31-4, 4-8.a] |
energy fluence rate (energy flux density) | At a given point in space, the sum of the energies, exclusive of rest energy, of all the particles incident on a small sphere in a small time interval, divided by the cross-sectional area of that sphere and by the time interval. | [I31-10, 10-11.a] | ||||
irradiance | At a point on a surface, the radiant energy flux incident on (or leaving) an element of the surface, divided by the area of that element. | [I31-6, 6-16.a] | ||||
Poynting vector | The vector product of electric field strength and magnetic field strength. | [I31-5, 5-31.a] | ||||
radiant energy fluence rate | At a given point in space, the radiant flux incident on a small sphere over a short time interval, divided by the cross-sectional area of that sphere and that time. | [I31-6, 6-12.a] | ||||
radiant exitance | At a point on a surface, the radiant energy flux incident on an element of the surface, divided by the area of that element. | [I31-6, 6-15.a] | ||||
sound intensity | For unidirectional sound power, sound power through a surface normal to the direction of propagation divided by the area of the surface. | [I31-7, 7-17.a] | ||||
WATT_PER_SQ_METRE_K | W/(m2 · K) | coefficient of heat transfer | The heat flow rate divided by area. 1 W/(m2 · K) = 1 kg/(s3 · K). |
COEFFICIENT_HEAT- _TRANSFER |
235 | [I31-4, 4-10.a] |
WATT_PER_SQ_METRE_MICRON | W/(m2 · μm) | integrated spectral radiance | At a point on a surface and integrated over all directions, the radiant intensity of an element of the surface, divided by the area of the orthogonal projection of this element on a plane perpendicular to the given direction, as a function of radiant wavelength. 1 W/(m2 · μm) = 1 kg/(s3 · μm). |
SPECTRAL_RADIANCE- _INTEGRATED |
236 | [I31-0, 2.3.2.2 (derived)] |
WATT_PER_SQ_METRE_SEC | W/(m2 · s) | radiant exitance rate | At a point on a surface, the radiant energy flux leaving the element of the surface over an interval of time, divided by the area of that element and that time. 1 W/(m2 · s) = 1 kg/s4. |
RADIANT_EXITANCE- _RATE |
237 | [I31-0, 2.3.2.2 (derived)] |
WATT_PER_SQ_METRE_SR | W/(m2 · sr) | total radiance | At a point on a surface and in a given direction, the spectrally integrated radiant intensity of an element of the surface, divided by the area of the orthogonal projection of this element on a plane perpendicular to the given direction. 1 W/(m2 · sr) = 1 kg/(s3 · sr). |
RADIANCE | 238 | [I31-6, 6-14.a] |
WATT_PER_SQ_METRE_SR_MICRON | W/(m2 · sr · μm) | spectral radiance | At a point on a surface and in a given direction, the radiant intensity of an element of the surface, divided by the area of the orthogonal projection of this element on a plane perpendicular to the given direction, as a function of radiant wavelength. 1 W/(m2 · sr · μm) = 1 kg/(s3 · sr · μm). |
SPECTRAL_RADIANCE | 239 | [I31-0, 2.3.2.2 (derived)] |
WATT_PER_STERADIAN | W/sr | radiant intensity | In a given direction from a source, the radiant energy flux leaving the source, or an element of the source, in an element of solid angle containing the given direction, divided by that element of solid angle. 1 W/sr = 1 (m2 · kg)/(s3 · sr). |
RADIANT_INTENSITY | 240 | [I31-6, 6-13.a] |
WATT_SECOND | W · s | electrical active energy | The practical unit of energy in electrical systems. 1 W · s = 1 J (exactly). |
ENERGY | 241 | [I31-0, Table 2, I31-0, 2.3.2.2 (derived)] |
WATT_SQ_METRE | W · m2 | first radiation constant | The constant c1 in the expression for the spectral concentration of the radiant exitance of a full radiator (black body). 1 W · m2 = 1 (m4 · kg)/s3. |
FIRST_RADIATION- _CONSTANT |
242 | [I31-6, 6-19.a] |
WEBER | Wb | magnetic flux | Across a surface element, the scalar product of the magnetic flux density and the surface element. 1 Wb = 1 V · s = 1 (m2 · kg)/(s2 · A). |
MAGNETIC_FLUX | 243 | [I31-0, Table 2], [I31-5, 5-20.a] |
WEBER_PER_METRE | Wb/m | magnetic vector potential | A vector quantity, the rotation (curl) of which is equal to the magnetic flux density. 1 Wb/m = 1 (m · kg)/(s2 · A). |
MAGNETIC_VECTOR- _POTENTIAL |
244 | [I31-5, 5-21.a] |