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SI derived unit
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SI derived units are units of measurement derived from the seven SI base units specified by the International System of Units (SI). They can be expressed as a product (or ratio) of one or more of the base units, possibly scaled by an appropriate power of exponentiation (see: Buckingham π theorem). Some are dimensionless, as when the units cancel out in ratios of like quantities. SI coherent derived units involve only a trivial proportionality factor, not requiring conversion factors.
The SI has special names for 22 of these coherent derived units (for example, hertz, the SI unit of measurement of frequency), but the rest merely reflect their derivation: for example, the square metre (m2), the SI derived unit of area; and the kilogram per cubic metre (kg/m3 or kg⋅m−3), the SI derived unit of density.
The names of SI coherent derived units, when written in full, are always in lowercase. However, the symbols for units named after persons are written with an uppercase initial letter. For example, the symbol for hertz is "Hz", while the symbol for metre is "m".[1]
Special names
[edit]The International System of Units assigns special names to 22 derived units, which includes two dimensionless derived units, the radian (rad) and the steradian (sr).
By field of application
[edit]Kinematics
[edit]| Name | Symbol | Quantity | Expression in terms of SI base units |
|---|---|---|---|
| metre per second | m/s | speed, velocity | m⋅s−1 |
| metre per second squared | m/s2 | acceleration | m⋅s−2 |
| metre per second cubed | m/s3 | jerk, jolt | m⋅s−3 |
| metre per second to the fourth | m/s4 | snap, jounce | m⋅s−4 |
| kilogram metre per second to the third | kg⋅m/s3 | yank | m⋅kg⋅s−3 |
| radian per second | rad/s | angular velocity | s−1 |
| radian per second squared | rad/s2 | angular acceleration | s−2 |
| hertz per second | Hz/s | frequency drift | s−2 |
| cubic metre per second | m3/s | volumetric flow | m3⋅s−1 |
Mechanics
[edit]| Name | Symbol | Quantity | Expression in terms of SI base units |
|---|---|---|---|
| square metre | m2 | area | m2 |
| cubic metre | m3 | volume | m3 |
| newton-second | N⋅s | momentum, impulse | m⋅kg⋅s−1 |
| newton metre second | N⋅m⋅s | angular momentum | m2⋅kg⋅s−1 |
| newton-metre | N⋅m = J/rad | torque, moment of force | m2⋅kg⋅s−2 |
| newton per second | N/s | yank | m⋅kg⋅s−3 |
| reciprocal metre | m−1 | wavenumber, optical power, curvature, spatial frequency | m−1 |
| kilogram per square metre | kg/m2 | area density | m−2⋅kg |
| kilogram per cubic metre | kg/m3 | density, mass density | m−3⋅kg |
| cubic metre per kilogram | m3/kg | specific volume | m3⋅kg−1 |
| joule-second | J⋅s | action | m2⋅kg⋅s−1 |
| joule per kilogram | J/kg | specific energy | m2⋅s−2 |
| joule per cubic metre | J/m3 | energy density | m−1⋅kg⋅s−2 |
| newton per metre | N/m = J/m2 | surface tension, stiffness | kg⋅s−2 |
| watt per square metre | W/m2 | heat flux density, irradiance | kg⋅s−3 |
| square metre per second | m2/s | kinematic viscosity, thermal diffusivity, diffusion coefficient | m2⋅s−1 |
| pascal-second | Pa⋅s = N⋅s/m2 | dynamic viscosity | m−1⋅kg⋅s−1 |
| kilogram per metre | kg/m | linear mass density | m−1⋅kg |
| kilogram per second | kg/s | mass flow rate | kg⋅s−1 |
| watt per steradian square metre | W/(sr⋅m2) | radiance | kg⋅s−3 |
| watt per steradian cubic metre | W/(sr⋅m3) | radiance | m−1⋅kg⋅s−3 |
| watt per metre | W/m | spectral power | m⋅kg⋅s−3 |
| gray per second | Gy/s | absorbed dose rate | m2⋅s−3 |
| metre per cubic metre | m/m3 | fuel efficiency | m−2 |
| watt per cubic metre | W/m3 | spectral irradiance, power density | m−1⋅kg⋅s−3 |
| joule per square metre second | J/(m2⋅s) | energy flux density | kg⋅s−3 |
| reciprocal pascal | Pa−1 | compressibility | m⋅kg−1⋅s2 |
| joule per square metre | J/m2 | radiant exposure | kg⋅s−2 |
| kilogram square metre | kg⋅m2 | moment of inertia | m2⋅kg |
| newton metre second per kilogram | N⋅m⋅s/kg | specific angular momentum | m2⋅s−1 |
| watt per steradian | W/sr | radiant intensity | m2⋅kg⋅s−3 |
| watt per steradian metre | W/(sr⋅m) | spectral intensity | m⋅kg⋅s−3 |
Chemistry
[edit]| Name | Symbol | Quantity | Expression in terms of SI base units |
|---|---|---|---|
| mole per cubic metre | mol/m3 | molarity, amount of substance concentration | m−3⋅mol |
| cubic metre per mole | m3/mol | molar volume | m3⋅mol−1 |
| joule per kelvin mole | J/(K⋅mol) | molar heat capacity, molar entropy | m2⋅kg⋅s−2⋅K−1⋅mol−1 |
| joule per mole | J/mol | molar energy | m2⋅kg⋅s−2⋅mol−1 |
| siemens square metre per mole | S⋅m2/mol | molar conductivity | kg−1⋅s3⋅A2⋅mol−1 |
| mole per kilogram | mol/kg | molality | kg−1⋅mol |
| kilogram per mole | kg/mol | molar mass | kg⋅mol−1 |
| cubic metre per mole second | m3/(mol⋅s) | catalytic efficiency | m3⋅s−1⋅mol−1 |
Electromagnetics
[edit]| Name | Symbol | Quantity | Expression in terms of SI base units |
|---|---|---|---|
| coulomb per square metre | C/m2 | electric displacement field, polarization density | m−2⋅s⋅A |
| coulomb per cubic metre | C/m3 | electric charge density | m−3⋅s⋅A |
| ampere per square metre | A/m2 | electric current density | m−2⋅A |
| siemens per metre | S/m | electrical conductivity | m−3⋅kg−1⋅s3⋅A2 |
| farad per metre | F/m | permittivity | m−3⋅kg−1⋅s4⋅A2 |
| henry per metre | H/m | magnetic permeability | m⋅kg⋅s−2⋅A−2 |
| volt per metre | V/m | electric field strength | m⋅kg⋅s−3⋅A−1 |
| ampere per metre | A/m | magnetization, magnetic field strength | m−1⋅A |
| coulomb per kilogram | C/kg | exposure (X and gamma rays) | kg−1⋅s⋅A |
| ohm metre | Ω⋅m | resistivity | m3⋅kg⋅s−3⋅A−2 |
| coulomb per metre | C/m | linear charge density | m−1⋅s⋅A |
| joule per tesla | J/T | magnetic dipole moment | m2⋅A |
| square metre per volt second | m2/(V⋅s) | electron mobility | kg−1⋅s2⋅A |
| reciprocal henry | H−1 | magnetic reluctance | m−2⋅kg−1⋅s2⋅A2 |
| weber per metre | Wb/m | magnetic vector potential | m⋅kg⋅s−2⋅A−1 |
| weber metre | Wb⋅m | magnetic moment | m3⋅kg⋅s−2⋅A−1 |
| tesla metre | T⋅m | magnetic rigidity | m⋅kg⋅s−2⋅A−1 |
| ampere radian | A⋅rad | magnetomotive force | A |
| metre per henry | m/H | magnetic susceptibility | m−1⋅kg−1⋅s2⋅A2 |
Photometry
[edit]| Name | Symbol | Quantity | Expression in terms of SI base units |
|---|---|---|---|
| lumen second | lm⋅s | luminous energy | s⋅cd |
| lux second | lx⋅s | luminous exposure | m−2⋅s⋅cd |
| candela per square metre | cd/m2 | luminance | m−2⋅cd |
| lumen per watt | lm/W | luminous efficacy | m−2⋅kg−1⋅s3⋅cd |
Thermodynamics
[edit]| Name | Symbol | Quantity | Expression in terms of SI base units |
|---|---|---|---|
| joule per kelvin | J/K | heat capacity, entropy | m2⋅kg⋅s−2⋅K−1 |
| joule per kilogram kelvin | J/(K⋅kg) | specific heat capacity, specific entropy | m2⋅s−2⋅K−1 |
| watt per metre kelvin | W/(m⋅K) | thermal conductivity | m⋅kg⋅s−3⋅K−1 |
| kelvin per watt | K/W | thermal resistance | m−2⋅kg−1⋅s3⋅K |
| reciprocal kelvin | K−1 | thermal expansion coefficient | K−1 |
| kelvin per metre | K/m | temperature gradient | m−1⋅K |
Other units used with SI
[edit]Some other units such as the hour, litre, tonne, bar, and electronvolt are not SI units, but are widely used in conjunction with SI units.
Supplementary units
[edit]Until 1995, the SI classified the radian and the steradian as supplementary units, but this designation was abandoned and the units were grouped as derived units.[3]
See also
[edit]References
[edit]- ^ Suplee, Curt (2 July 2009). "Special Publication 811". Nist.
- ^ International Bureau of Weights and Measures (2006), The International System of Units (SI) (PDF) (8th ed.), ISBN 92-822-2213-6, archived (PDF) from the original on 4 June 2021, retrieved 16 December 2021
- ^ "Resolution 8 of the CGPM at its 20th Meeting (1995)". Bureau International des Poids et Mesures. Retrieved 23 September 2014.
Bibliography
[edit]External links
[edit]
Media related to SI derived units at Wikimedia Commons
SI derived unit
View on Grokipediafrom Grokipedia
| Derived Quantity | Name | Symbol | Expression in Base Units |
|---|---|---|---|
| Force | newton | N | kg·m·s⁻² |
| Pressure | pascal | Pa | kg·m⁻¹·s⁻² |
| Energy | joule | J | kg·m²·s⁻² |
| Power | watt | W | kg·m²·s⁻³ |
| Electric charge | coulomb | C | s·A |
| Electric potential difference | volt | V | kg·m²·s⁻³·A⁻¹ |
| Capacitance | farad | F | kg⁻¹·m⁻²·s⁴·A² |
Fundamentals of SI Units
Base Units and the SI System
The International System of Units (SI), known as the modern form of the metric system, was formally adopted in 1960 by the 11th General Conference on Weights and Measures (CGPM) through Resolution 12, which established a coherent framework for scientific and everyday measurements based on seven base quantities and their corresponding units.[3][4] This system builds on earlier metric developments, such as the metre-kilogram-second (MKS) framework, to provide a universal standard that facilitates international consistency in measurement.[5] The SI defines seven base quantities, each with a dedicated base unit, selected to cover fundamental aspects of physical measurement without redundancy. These are: length, measured in the metre (m); mass, in the kilogram (kg); time, in the second (s); electric current, in the ampere (A); thermodynamic temperature, in the kelvin (K); amount of substance, in the mole (mol); and luminous intensity, in the candela (cd).[6][4]| Base Quantity | Base Unit | Symbol | Definition (post-2019) |
|---|---|---|---|
| Length | metre | m | The metre is defined by taking the fixed numerical value of the speed of light in vacuum c to be 299792458 m/s, with the second fixed by definition.[7] |
| Mass | kilogram | kg | The kilogram is defined by taking the fixed numerical value of the Planck constant h to be 6.62607015 × 10-34 J s, with the joule and second fixed by definition. |
| Time | second | s | The second is defined by taking the fixed numerical value of the caesium frequency ΔνCs, the unperturbed ground-state hyperfine transition frequency of the caesium-133 atom, to be 9192631770 Hz.[8] |
| Electric current | ampere | A | The ampere is defined by taking the fixed numerical value of the elementary charge e to be 1.602176634 × 10-19 C, with the coulomb and second fixed by definition. |
| Thermodynamic temperature | kelvin | K | The kelvin is defined by taking the fixed numerical value of the Boltzmann constant k to be 1.380649 × 10-23 J/K, with the joule and second fixed by definition. |
| Amount of substance | mole | mol | The mole is defined by taking the fixed numerical value of the Avogadro constant NA to be 6.02214076 × 1023 mol-1. |
| Luminous intensity | candela | cd | The candela is defined by taking the fixed numerical value of the luminous efficacy of monochromatic radiation of frequency 540 × 1012 Hz, Kcd, to be 683 lm/W, with the second and metre fixed by definition. |
Definition of Derived Units
In the International System of Units (SI), derived units are those used to express quantities that are functions of the seven base quantities, formed by taking products or quotients of powers of the corresponding base units.[4] These units arise from the algebraic relations linking derived quantities to base quantities, such as velocity, which is defined as the quotient of length and time, yielding the unit metre per second (m/s).[4] Every physical quantity in the SI possesses a dimension, expressed as a product of powers of the dimensions of the base quantities, denoted symbolically as , where L, M, T, I, Θ, N, and J represent length, mass, time, electric current, thermodynamic temperature, amount of substance, and luminous intensity, respectively, and the exponents a through g are integers (positive, negative, or zero).[4] The derived unit for a given quantity must then match this dimensional expression through appropriate combinations of base units, ensuring dimensional homogeneity in physical equations.[4] A key feature of the SI is the principle of coherence, whereby coherent derived units are specifically chosen as products of integer powers of base units with no additional numerical factor other than unity.[4] This ensures that the equations between numerical values of physical quantities take exactly the same form as the equations between the quantities themselves, eliminating the need for conversion factors in fundamental relations.[4] For instance, the coherent derived unit for area is the square metre (m²), obtained as length squared, and for volume, it is the cubic metre (m³), as length cubed.[4]Coherent Derived Units
Units with Special Names
Coherent derived units in the SI that appear frequently in scientific and technical contexts are assigned special names and symbols to enhance clarity and convenience, thereby avoiding lengthy expressions composed solely of base units. For example, the unit for force is designated as the newton rather than kilogram meter per second squared.[4] These special names originated from earlier metric systems and were progressively formalized through decisions by the General Conference on Weights and Measures (CGPM). The 9th CGPM in 1948 adopted names such as newton, joule, watt, and others derived from the metre-kilogram-second (MKS) system.[4] The 11th CGPM in 1960 established the SI and confirmed many of these names, including hertz, pascal, coulomb, volt, and farad.[4] Subsequent conferences added names like becquerel and gray (15th CGPM, 1975), sievert (16th CGPM, 1979), and katal (21st CGPM, 1999) to address emerging needs in radioactivity, radiation protection, and chemistry.[4] The 22 coherent derived units with special names, as defined in the 9th edition of the SI Brochure (2019, revised 2025), are presented in the table below. Each entry includes the unit name, symbol, physical quantity, expression in terms of SI base units, and a brief etymology.[4]| Name | Symbol | Quantity | Expression in Terms of Base Units | Etymology |
|---|---|---|---|---|
| radian | rad | plane angle | 1 | Derived from "radius," referring to the arc length equal to the radius.[4] |
| steradian | sr | solid angle | 1 | Derived from Greek "stereos" (solid) and "radius."[4] |
| hertz | Hz | frequency | s⁻¹ | Named after Heinrich Hertz, German physicist who studied electromagnetic waves.[4] |
| newton | N | force, weight | kg⋅m⋅s⁻² | Named after Sir Isaac Newton, English mathematician and physicist.[4] |
| pascal | Pa | pressure, stress | kg⋅m⁻¹⋅s⁻² | Named after Blaise Pascal, French mathematician and physicist.[4] |
| joule | J | energy, work, quantity of heat | kg⋅m²⋅s⁻² | Named after James Prescott Joule, English physicist.[4] |
| watt | W | power, radiant flux | kg⋅m²⋅s⁻³ | Named after James Watt, Scottish engineer and inventor.[4] |
| coulomb | C | electric charge, quantity of electricity | s⋅A | Named after Charles-Augustin de Coulomb, French physicist.[4] |
| volt | V | electric potential, potential difference, electromotive force | kg⋅m²⋅s⁻³⋅A⁻¹ | Named after Alessandro Volta, Italian physicist.[4] |
| farad | F | capacitance | kg⁻¹⋅m⁻²⋅s⁴⋅A² | Named after Michael Faraday, English physicist and chemist.[4] |
| ohm | Ω | electric resistance, impedance, reactance | kg⋅m²⋅s⁻³⋅A⁻² | Named after Georg Simon Ohm, German physicist.[4] |
| siemens | S | electric conductance, admittance, susceptance | kg⁻¹⋅m⁻²⋅s³⋅A² | Named after Ernst Werner von Siemens, German industrialist and inventor.[4] |
| weber | Wb | magnetic flux | kg⋅m²⋅s⁻²⋅A⁻¹ | Named after Wilhelm Eduard Weber, German physicist.[4] |
| tesla | T | magnetic flux density, magnetic induction | kg⋅s⁻²⋅A⁻¹ | Named after Nikola Tesla, Serbian-American inventor and engineer.[4] |
| henry | H | inductance, mutual inductance | kg⋅m²⋅s⁻²⋅A⁻² | Named after Joseph Henry, American physicist.[4] |
| degree Celsius | °C | Celsius temperature (interval) | K | Named after Anders Celsius, Swedish astronomer.[4] |
| lumen | lm | luminous flux | cd⋅sr | From Latin "lumen," meaning light.[4] |
| lux | lx | illuminance, illumination | cd⋅m⁻² | From Latin "lux," meaning light.[4] |
| becquerel | Bq | radioactive activity | s⁻¹ | Named after Henri Becquerel, French physicist and discoverer of radioactivity.[4] |
| gray | Gy | absorbed dose, specific energy imparted, kerma, absorbed dose index | m²⋅s⁻² | Named after Louis Harold Gray, British radiobiologist.[4] |
| sievert | Sv | dose equivalent, dose equivalent index | m²⋅s⁻² | Named after Rolf Maximilian Sievert, Swedish medical physicist.[4] |
| katal | kat | catalytic activity | mol⋅s⁻¹ | Derived from Greek "katalyein," meaning to dissolve or loosen.[4] |
Units without Special Names
Coherent derived units without special names are those expressed directly as products or quotients of powers of SI base units, with no additional numerical factors other than unity. These units maintain the coherence of the SI system by ensuring that the algebraic relations between quantities translate directly into equations between their numerical values without conversion factors. For instance, the unit for area is the square metre, denoted as m², formed by the square of the base unit of length. Similarly, volume uses the cubic metre, m³, as the product of three length units. Speed, or velocity magnitude, is represented by the metre per second, m/s, which is length divided by time. Acceleration follows as metre per second squared, m/s², incorporating time in the denominator twice. Density is kilogram per cubic metre, kg/m³, combining mass with the inverse of volume. Momentum employs kilogram metre per second, kg⋅m/s, as the product of mass and speed. For frequency, the coherent unit is the reciprocal second, s⁻¹, though it has a special name alternative in common use. These compound units preserve coherence in physical equations by aligning dimensions directly. Consider the kinetic energy formula $ E = \frac{1}{2} m v^2 $, where mass $ m $ is in kilograms (kg) and speed $ v $ is in metres per second (m/s); the resulting energy unit is then kg⋅m²⋅s⁻², which corresponds to the joule (detailed elsewhere). This direct substitution avoids scaling factors, allowing the equation to hold numerically as it does dimensionally. While these units provide a systematic and universal approach to measurement, their compound expressions can become lengthy for quantities involving multiple base units or higher powers. In practice, this complexity often motivates the assignment of special names to frequently used derived units, enhancing readability and reducing error in complex calculations.Derived Units by Physical Dimension
Dimensions Involving Length and Time
Derived units involving only the dimensions of length [L] and time [T] form a foundational subset in the SI system, enabling the quantification of kinematic and dynamic phenomena without introducing other base quantities. These units are coherent, meaning they arise directly from products or quotients of the base units of length (metre, m) and time (second, s) with numerical factors of unity, ensuring that fundamental physical equations retain their simplest numerical form when expressed in SI units.[4] The dimensional formula for velocity, a measure of speed or rate of change of position, is [L T^{-1}], with the coherent SI unit being the metre per second (m/s). This unit represents the distance traveled in one second, directly linking the metre—defined since 1983 as the distance light travels in vacuum in 1/299 792 458 of a second—to the second, which is based on the caesium-133 hyperfine transition frequency of exactly 9 192 631 770 Hz. As of November 2025, ongoing efforts by the Consultative Committee for Time and Frequency (CCTF) and the CGPM are advancing proposals to redefine the second based on optical transitions for improved accuracy, with draft resolutions under consideration.[11][12] The 1983 redefinition of the metre, adopted by the 17th General Conference on Weights and Measures (CGPM), anchored length measurements to the invariant speed of light, thereby enhancing the precision and universality of velocity derivations across length-time combinations.[7][4] Acceleration, the rate of change of velocity, has the dimensional formula [L T^{-2}] and the coherent unit metre per second squared (m/s²). This unit captures changes in motion, such as gravitational acceleration near Earth's surface at approximately 9.8 m/s². Coherence is exemplified in kinematic equations, such as the linear form $ v = u + at $, where initial velocity $ u $ and final velocity $ v $ are in m/s, acceleration $ a $ is in m/s², and time $ t $ is in s; substituting these units yields m/s = m/s + (m/s²) × s, confirming dimensional balance without conversion factors. This property simplifies calculations in mechanics, as the equation's numerical coefficients remain unchanged in the SI system.[4] Frequency, denoting cycles or oscillations per unit time, possesses the dimensional formula [T^{-1}] and the coherent unit second inverse (s^{-1}), which received the special name hertz (Hz) in 1960 by the 11th CGPM to honor Heinrich Hertz's contributions to electromagnetism. One hertz equals one event per second, applicable to phenomena like sound waves or atomic transitions underlying the second's definition. While primarily time-based, frequency often pairs with length in wave contexts, such as wavelength $ \lambda = c / f $, where speed of light $ c $ is in m/s and frequency $ f $ in Hz, yielding metres.[4] Angular velocity, the rate of rotational change, shares the [T^{-1}] dimension and uses the unit radian per second (rad/s). The radian (rad), historically a supplementary unit since the 11th CGPM in 1960,[3] was reclassified as a derived dimensionless unit in 1995 by the 20th CGPM, as it equals the ratio of arc length to radius (both in metres), resulting in m/m = 1. Thus, rad/s coherently expresses angular rates, such as Earth's rotation at about 7.29 × 10^{-5} rad/s, integrating seamlessly with linear velocity via $ v = \omega r $ (m/s = rad/s × m). This evolution reflects the SI's refinement toward treating plane angles as derived quantities.[13][14][4]Dimensions Involving Mass and Force
In the International System of Units (SI), dimensions involving mass and force primarily combine the base dimensions of mass [M], length [L], and time [T] to quantify mechanical phenomena such as motion, interaction, and energy transfer. These derived units are coherent, meaning they follow directly from products and powers of the SI base units without additional numerical factors. The foundational quantity here is force, which arises from Newton's second law of motion, expressed as , where is force, is mass, and is acceleration.[4] The dimensional formula for force is , and its SI unit is the newton (N), defined as the force that imparts an acceleration of one meter per second squared to a mass of one kilogram, yielding . This unit was adopted as a special name by the 9th General Conference on Weights and Measures (CGPM) in 1948. Momentum, a related quantity representing the product of mass and velocity, has the dimensional formula and the unit , without a special name.[4][4][4] Pressure, defined as force per unit area, has the dimensional formula and the unit pascal (Pa), equivalent to . The pascal was adopted as a special name by the 14th CGPM in 1971, honoring Blaise Pascal (1623–1662), the French mathematician, physicist, and philosopher known for his contributions to hydrodynamics and atmospheric pressure studies. Energy or work, the scalar product of force and displacement, carries the dimensional formula and the unit joule (J), where , also named in 1948 by the 9th CGPM after James Prescott Joule. Power, the rate of energy transfer, has the dimensional formula and the unit watt (W), defined as , adopted in 1960 by the 11th CGPM to honor James Watt.[4][4][4][4][4][4] Other derived units in this category include surface tension, with dimensional formula and unit , representing force per unit length at interfaces, and dynamic viscosity, with dimensional formula and unit , measuring a fluid's resistance to shear flow. These units enable precise quantification in mechanics, from structural engineering to fluid dynamics, ensuring consistency across scientific and technical applications.[4][4]| Quantity | Dimensional Formula | SI Unit | Expression in Base Units |
|---|---|---|---|
| Momentum | kg⋅m⋅s⁻¹ | kg⋅m⋅s⁻¹ | |
| Force | Newton (N) | kg⋅m⋅s⁻² | |
| Pressure | Pascal (Pa) | kg⋅m⁻¹⋅s⁻² | |
| Energy/Work | Joule (J) | kg⋅m²⋅s⁻² | |
| Power | Watt (W) | kg⋅m²⋅s⁻³ | |
| Surface Tension | N⋅m⁻¹ | kg⋅s⁻² | |
| Dynamic Viscosity | Pa⋅s | kg⋅m⁻¹⋅s⁻¹ |
Dimensions Involving Electric Current and Charge
In the International System of Units (SI), electric current is a base quantity with dimension symbol [I], and its SI unit is the ampere (A).[4] Electric charge, a derived quantity, has the dimensional formula [I T], where [T] denotes time, and its coherent SI unit is the coulomb (C), defined as C = A ⋅ s.[4] This unit quantifies the amount of electric charge transported by a current of one ampere in one second, establishing the foundational role of [I] in electromagnetic dimensions.[4] Electric potential difference, another key derived quantity, has the dimensional formula [M L² T⁻³ I⁻¹], where [M] and [L] represent mass and length, respectively, linking electrical phenomena to mechanical energy components through the joule (J = kg ⋅ m² ⋅ s⁻²).[4] Its coherent SI unit is the volt (V), defined as V = kg ⋅ m² ⋅ s⁻³ ⋅ A⁻¹, equivalent to the potential difference across a conductor carrying one ampere of current that dissipates one watt of power.[4] From this, further derived units emerge, such as capacitance with unit farad (F = C / V = kg⁻¹ ⋅ m⁻² ⋅ s⁴ ⋅ A²), representing the ability to store one coulomb of charge at one volt.[4] Electrical resistance has the dimensional formula [M L² T⁻³ I⁻²] and unit ohm (Ω = V / A = kg ⋅ m² ⋅ s⁻³ ⋅ A⁻²), measuring opposition to current flow.[4] This coherence is exemplified in Ohm's law, V = I R, where the dimensions align as [M L² T⁻³ I⁻¹] = [I] ⋅ [M L² T⁻³ I⁻²], ensuring consistent numerical relations without conversion factors in SI equations.[15] Magnetic flux, with dimensional formula [M L² T⁻² I⁻¹], uses the weber (Wb = V ⋅ s = kg ⋅ m² ⋅ s⁻² ⋅ A⁻¹), while inductance has [M L² T⁻² I⁻²] and unit henry (H = Wb / A = kg ⋅ m² ⋅ s⁻² ⋅ A⁻²).[4] The definition of the ampere underwent a significant revision in 2019, when the 26th General Conference on Weights and Measures (CGPM) fixed the value of the elementary charge e exactly at 1.602 176 634 × 10⁻¹⁹ C, effective from 20 May 2019.[4] This replaced the prior definition based on the force between current-carrying conductors, anchoring the ampere—and thus all charge-related units—to fundamental constants for greater precision and universality.[4]Derived Units by Field of Application
Mechanics and Dynamics
In mechanics and dynamics, the newton (N), defined as the force required to accelerate a one-kilogram mass by one meter per second squared (kg⋅m⋅s⁻²), is fundamental for quantifying forces in structural engineering, such as the load-bearing capacities of bridges or buildings where forces are expressed in newtons to ensure material integrity.[4] The joule (J), equivalent to one newton-meter (N⋅m or kg⋅m²⋅s⁻²), measures energy transferred in mechanical processes, including kinetic energy dissipated during vehicle collisions, where impact energies can reach thousands of joules depending on speed and mass.[16] Similarly, the pascal (Pa), or one newton per square meter (N⋅m⁻² or kg⋅m⁻¹⋅s⁻²), quantifies pressure in fluid dynamics, such as hydraulic systems in machinery, and stress in solid materials under deformation.[17] Key derived quantities in classical mechanics include impulse, which represents the change in momentum and has units of N⋅s (or kg⋅m⋅s⁻¹), applied in analyzing impacts like those in sports equipment design to minimize injury.[4] Torque, the rotational equivalent of force, uses units of N⋅m (kg⋅m²⋅s⁻²) and is distinct from energy despite dimensional similarity, as the joule is not used for torque to avoid confusion in engineering contexts like bolt tightening.[18] Stress, measured in pascals, describes force per unit area in materials under load, while strain is dimensionless; together, they inform elastic moduli in structural analysis, such as in steel beams where stresses rarely exceed 250 MPa.[17] Moment of inertia, a measure of rotational resistance, has coherent SI units of kg⋅m² and is essential for calculating angular acceleration in systems like flywheels.[4] The work-energy theorem states that the net work done on an object equals the change in its mechanical energy, expressed as $ W = \Delta E $, where both work $ W $ and energy $ \Delta E $ are in joules, linking force application over distance to energy transformations in dynamic systems. Power, the rate of work or energy transfer, is given by $ P = F \cdot v $, with units of watts (W = J/s = N⋅m/s), illustrating how force $ F $ (in newtons) applied over velocity $ v $ (in m/s) yields power in applications like engine performance.[19] In modern aerospace engineering, derived units like the newton are critical for thrust measurements; for instance, NASA's model rocket engines, such as the C6-4, produce an average thrust of 6 N to propel payloads, scaling to millions of newtons in large orbital launch vehicles for precise trajectory control.[20]Electromagnetism
In electromagnetism, SI derived units quantify fundamental quantities such as electric potential, current, and magnetic fields, enabling precise descriptions of phenomena ranging from circuit behavior to electromagnetic waves. The volt (V), the unit of electric potential difference and electromotive force, is expressed as kg·m²·s⁻³·A⁻¹ and represents the potential difference that produces 1 joule of energy per coulomb of charge.[4] In electrical circuits, voltage drives current flow, with the ampere (A), the base unit of electric current, serving as the reference; for instance, Ohm's law relates voltage, current, and resistance via V = I·R, where resistance is measured in ohms (Ω = kg·m²·s⁻³·A⁻²).[4] Current density, denoted in amperes per square meter (A/m²), describes the electric current per unit cross-sectional area and is crucial for analyzing conductors and semiconductors, expressed dimensionally as A·m⁻².[4] Magnetic field strength uses amperes per meter (A/m), quantifying the magnetomotive force per unit length in materials like solenoids.[4] Permittivity (F/m), the measure of a material's ability to store electric charge, and permeability (H/m), which indicates magnetic response, are both per-unit-length derived units: F/m = kg⁻¹·m⁻³·s⁴·A² and H/m = kg·m·s⁻²·A⁻², respectively, influencing wave propagation in media.[4] Key examples include the electric field strength, in volts per meter (V/m = kg·m·s⁻³·A⁻¹), which describes the force per unit charge in electrostatics, and the magnetic flux density, in teslas (T = kg·s⁻²·A⁻¹), essential for motors and MRI imaging.[4] Impedance (Ω), extending resistance to AC circuits, combines these in phasor analysis for signal processing.[4] A foundational equation is Coulomb's law, expressing the electrostatic force between charges:
where is in newtons (N = kg·m·s⁻²), and in coulombs (C = A·s), in meters (m), and (vacuum permittivity) in F/m; unit analysis confirms consistency, as N derives from C²/(F·m²).[4]
In quantum electromagnetism, the 2019 SI revision—effective since May 20, 2019—facilitates precise photon energy calculations, where the electronvolt (eV), accepted for use with SI despite being non-SI, equals exactly 1.602176634 × 10⁻¹⁹ J and quantifies energies in atomic transitions and particle interactions.[4][21]
Thermodynamics and Chemistry
In thermodynamics and chemistry, SI derived units quantify properties related to heat, energy transfer, substance amounts, and reaction dynamics, building on base units like the kelvin (K) for temperature, mole (mol) for amount of substance, and joule (J) for energy.[4] These units enable precise descriptions of thermal processes, phase changes, and chemical equilibria without introducing non-coherent factors.[22] For instance, heat-related quantities often combine energy with temperature, while chemical ones incorporate the mole to express per-substance metrics. The dalton (Da), an accepted unit for atomic and molecular mass used with the SI, was revised in the August 2025 update to the SI Brochure (version 3.02) based on the 2022 CODATA adjustment of fundamental constants.[4] Heat capacity, denoted C, measures the energy required to raise the temperature of a system by one kelvin and has the unit joule per kelvin (J/K), dimensionally kg⋅m²⋅s⁻²⋅K⁻¹.[4] The molar heat capacity, Cm, extends this to per mole of substance, using J/(mol⋅K) or kg⋅m²⋅s⁻²⋅mol⁻¹⋅K⁻¹, which is essential for comparing thermal responses in gases or solutions.[22] Entropy, S, quantifies the dispersal of energy or disorder in a system and shares the unit J/K (kg⋅m²⋅s⁻²⋅K⁻¹), as established by the second law of thermodynamics.[4] In chemical contexts, concentration c represents the amount of substance per unit volume, with the unit mol/m³ (mol⋅m⁻³), facilitating analysis of solution properties and reaction progress.[22] Reaction rate v, the change in concentration over time, uses mol/(m³⋅s) or mol⋅m⁻³⋅s⁻¹, capturing the speed of chemical transformations in homogeneous systems.[4] Enthalpy H, the total heat content at constant pressure, is expressed in joules (J, kg⋅m²⋅s⁻²), while Gibbs free energy G—the maximum reversible work available—also uses J, both often reported as molar values like kJ/mol for standard conditions.[22] Chemical potential μ, the partial molar Gibbs energy, employs J/mol (kg⋅m²⋅s⁻²⋅mol⁻¹) to describe how adding a substance affects system energy.[4] The ideal gas law illustrates unit coherence in thermodynamics:where pressure P is in pascals (Pa, kg⋅m⁻¹⋅s⁻²), volume V in cubic meters (m³), amount n in moles (mol), temperature T in kelvin (K), and the gas constant R in J/(mol⋅K) (kg⋅m²⋅s⁻²⋅mol⁻¹⋅K⁻¹), yielding Pa⋅m³ = J on both sides.[22] In electrochemistry, the volt (V, kg⋅m²⋅s⁻³⋅A⁻¹) serves as the unit for potential difference, representing energy per unit charge in cells and driving reactions like electrolysis.[4] For modern biochemistry, catalytic activity in enzymes is measured in katals (kat, mol⋅s⁻¹), where 1 kat equals one mole of substance transformed per second, standardizing enzyme kinetics.[4]
Photometry and Radiometry
Photometry measures light in quantities adapted to human visual perception, while radiometry quantifies electromagnetic radiation independent of vision. In the SI system, photometric units are derived from the base unit candela (cd) for luminous intensity and the supplementary unit steradian (sr) for solid angle, with radiometric units building on the watt (W) for power. These units enable precise characterization of light sources and illumination in applications ranging from lighting design to optical instrumentation.[4] Key photometric derived units include luminous flux, measured in lumens (lm), defined as the product of luminous intensity in candelas and solid angle in steradians: lm = cd ⋅ sr. This represents the total visible light output from a source, weighted by the eye's sensitivity. Illuminance, in lux (lx), quantifies light incident on a surface and is derived as luminous flux per unit area: lx = lm / m². Luminance, in candelas per square meter (cd/m²), describes the brightness of a surface or source in a given direction, combining luminous intensity per unit projected area.[4][23] Radiometric units provide physical counterparts without visual weighting. Radiant flux, the total power emitted as electromagnetic radiation, uses the watt (W), a derived unit from mechanics equivalent to kg ⋅ m² ⋅ s⁻³. Irradiance, the radiant flux per unit area on a surface, is thus W/m². The watt's origin in mechanical power underscores radiometry's foundation in energy transfer, distinct from photometry's perceptual basis.[4][23] The link between these domains is luminous efficacy, denoted $ K $, which converts radiant flux $ \Phi_e $ (in W) to luminous flux $ \Phi_v $ (in lm):
with units lm/W. This ratio quantifies how effectively a source produces visible light from radiant power, derived by applying spectral luminous efficiency functions to the source's spectrum and scaling by the maximum efficacy constant.
The candela was redefined in the 2019 SI revision, effective 20 May 2019, by fixing the luminous efficacy of monochromatic radiation at exactly 540 THz (corresponding to 555.017 nm wavelength) to 683 lm/W. Specifically, the candela is now the luminous intensity, in a given direction, of a source that emits monochromatic radiation at that frequency with radiant intensity of 1/683 W/sr. This anchors photometry directly to fundamental constants, enhancing traceability and stability.[4][23][24]
Post-2019, this redefinition facilitates tighter integration of radiometry and photometry for modern applications, particularly LEDs and lasers, whose narrowband spectra align closely with the fixed efficacy point. Realizations now employ detector-based methods like cryogenic radiometers or photon-counting techniques to calibrate these sources, improving accuracy in spectral power measurements and luminous output for energy-efficient lighting and precision optics. For instance, LED characterizations use the fixed $ K_{cd} $ with spectral weighting to derive photometric quantities from radiometric data, supporting advancements in solid-state lighting standards.[24]
Supplementary and Related Units
Supplementary Units
In the International System of Units (SI), supplementary units historically referred to a distinct class of units introduced to address quantities like angles that did not fit neatly into the base or derived categories. The only two units in this class were the radian (rad), the coherent SI unit for plane angle, and the steradian (sr), the coherent SI unit for solid angle. The radian is defined as the plane angle subtended at the center of a circle by an arc whose length is equal to the radius of the circle, while the steradian is defined as the solid angle subtended at the center of a sphere by a portion of the surface whose area is equal to the square of the radius of the sphere.[4] These units were established by the 11th Conférence Générale des Poids et Mesures (CGPM) in 1960 as supplementary units, separate from the seven base units and the derived units, due to uncertainty about their dimensional status.[3] The classification of radian and steradian as supplementary units persisted until 1995, when the 20th CGPM adopted Resolution 8, which eliminated the supplementary category entirely and reclassified these units as dimensionless derived units with a dimension of one ([L⁰]). This decision affirmed the interpretation by the International Committee for Weights and Measures (CIPM) in 1980 that supplementary units should be regarded as dimensionless, resolving earlier debates about whether angles possessed independent dimensions.[25][26] For historical and practical reasons, the radian and steradian are still expressed using their special names and symbols rather than simply "1," though they are fundamentally ratios: the radian as a ratio of two lengths (m/m), and the steradian as a ratio of an area to the square of a length (m²/m²). This dimensionless nature is illustrated in the formula for arc length, where the arc length equals the radius times the plane angle in radians:
Dimensionally, this yields meters (m) = m × (dimensionless), confirming that the radian cancels out without introducing new dimensions.[4]
The radian and steradian play essential roles in derived SI units involving angular measures. For instance, angular velocity is expressed in radians per second (rad/s), quantifying rotational speed in mechanics. In photometry, the steradian appears in the definition of the lumen (lm), the unit of luminous flux, as lm = cd ⋅ sr, where cd is the candela; this extends to illuminance in lux (lx = cd ⋅ sr / m²). These applications highlight how the supplementary units, now integrated as derived, facilitate coherent expressions across physics without altering the SI's dimensional framework.[4]
Non-SI Units Commonly Used with SI
Although the SI is a coherent system based on seven base units, certain non-SI units are accepted for use alongside SI units owing to their entrenched practical value in science, engineering, commerce, and daily life. These units are precisely defined in terms of SI units to ensure interoperability, and their acceptance is governed by resolutions of the General Conference on Weights and Measures (CGPM) and recommendations of the International Committee for Weights and Measures (CIPM). The BIPM maintains an official list, updated periodically, which prioritizes units that facilitate communication without undermining the SI framework.[4] Key categories encompass units for time, plane angle, volume, pressure, and energy. For time, the minute, hour, and day remain indispensable for scheduling and historical records, converting directly as multiples of the second. The degree provides intuitive expression for angular measurements in navigation, surveying, and mathematics, equivalent to a fraction of the radian. The litre serves as a convenient measure for liquids in chemistry, medicine, and trade, aligning exactly with the cubic decimetre. In pressure, the bar offers a round value close to standard atmospheric pressure, aiding engineering and meteorology. The electronvolt quantifies subatomic energies succinctly in particle physics and quantum mechanics, where SI joules would yield impractically small numbers. In addition, specialized units for navigation such as the nautical mile and knot persist in maritime and aviation standards for their historical ties to Earth's geometry, though not officially accepted and with the BIPM advocating gradual replacement with SI equivalents like the metre and metre per second to enhance global uniformity.[4] The table below summarizes selected non-SI units accepted for use with the SI, including exact conversion factors:| Category | Unit | Symbol | Conversion to SI Units |
|---|---|---|---|
| Time | minute | min | 1 min = 60 s |
| Time | hour | h | 1 h = 3600 s |
| Time | day | d | 1 d = 86 400 s |
| Angle | degree | ° | 1° = /180 rad |
| Volume | litre | L | 1 L = 1 dm³ = 10 m³ |
| Pressure | bar | bar | 1 bar = 10 Pa |
| Energy | electronvolt | eV | 1 eV = 1.602 × 10 J |