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A physical quantity is a physical property of a material or system that can be quantified by measurement. A physical quantity can be expressed as a value, which is the algebraic multiplication of a numerical value and a unit. For example, the physical quantity mass can be quantified as n kg, where n is the numerical value and kg is the unit. A physical quantity possesses at least two characteristics in common. One is numerical magnitude and the other is the unit in which it is measured.
International recommendations for the use of symbols for quantities are set out in ISO/IEC 80000, the IUPAP red book and the IUPAC green book. For example, the recommended symbol for the physical quantity mass is m, and the recommended symbol for the quantity electric charge is Q.
Subscripts are used for two reasons, to simply attach a name to the quantity or associate it with another quantity, or index a specific component (e.g., row or column).
The type of subscript is expressed by its typeface: 'k' and 'p' are abbreviations of the words kinetic and potential, whereas p (italic) is the symbol for the physical quantity pressure rather than an abbreviation of the word.
Physical quantities can have different "sizes", as a scalar, a vector, or a tensor.
A scalar is a physical quantity that has magnitude but no direction. Symbols for physical quantities are usually chosen to be a single letter of the Latin or Greek alphabet, and are printed in italic type.
Vectors are physical quantities that possess both magnitude and direction and whose operations obey the axioms of a vector space. Symbols for physical quantities that are vectors are in bold type, underlined or with an arrow above. For example, if u is the speed of a particle, then the straightforward notations for its velocity are u, u, or .
Scalars and vectors are the simplest tensors, which can be used to describe more general physical quantities. For example, the Cauchy stress tensor possess magnitude, direction, and orientation qualities.
Numerical quantities, even those denoted by letters, are usually printed in roman (upright) type, though sometimes in italic. Symbols for elementary functions (circular trigonometric, hyperbolic, logarithmic etc.), changes in a quantity like ? in ?y or operators like d in dx, are also recommended to be printed in roman type.
Examples:
There is often a choice of unit, though SI units (including submultiples and multiples of the basic unit) are usually used in scientific contexts due to their ease of use, international familiarity and prescription. For example, a quantity of mass might be represented by the symbol m, and could be expressed in the units kilograms (kg), pounds (lb), or daltons (Da).
The notion of dimension of a physical quantity was introduced by Joseph Fourier in 1822.^{[1]} By convention, physical quantities are organized in a dimensional system built upon base quantities, each of which is regarded as having its own dimension.
Base quantities are those quantities which are distinct in nature and in some cases have historically not been defined in terms of other quantities. Base quantities are those quantities on the basis of which other quantities can be expressed. The seven base quantities of the International System of Quantities (ISQ) and their corresponding SI units and dimensions are listed in the following table. Other conventions may have a different number of base units (e.g. the CGS and MKS systems of units).
Quantity  SI unit  Dimension symbol  

Name(s)  (Common) symbol(s)  Name  Symbol  
Length, width, height, depth, distance  a, b, c, d, h, l, r, s, w, x, y, z  metre  m  L 
Time  t, ?  second  s  T 
Mass  m  kilogram  kg  M 
Thermodynamic temperature  T, ?  kelvin  K  ? 
Amount of substance  n  mole  mol  N 
Electric current  i, I  ampere  A  I 
Luminous intensity  I_{v}  candela  cd  J 
Plane angle  ?, ?, ?, ?, ?, ?  radian  rad  None 
Solid angle  ?, ?  steradian  sr  None 
The last two angular units, plane angle and solid angle, are subsidiary units used in the SI, but are treated as dimensionless. The subsidiary units are used for convenience to differentiate between a truly dimensionless quantity (pure number) and an angle, which are different measurements.
Derived quantities are those whose definitions are based on other physical quantities (base quantities).
Important applied base units for space and time are below. Area and volume are thus, of course, derived from the length, but included for completeness as they occur frequently in many derived quantities, in particular densities.
Quantity  SI unit  Dimensions  

Description  Symbols  
(Spatial) position (vector)  r, R, a, d  m  L 
Angular position, angle of rotation (can be treated as vector or scalar)  ?, ?  rad  None 
Area, crosssection  A, S, ?  m^{2}  L^{2} 
Vector area (Magnitude of surface area, directed normal to tangential plane of surface)  m^{2}  L^{2}  
Volume  ?, V  m^{3}  L^{3} 
Important and convenient derived quantities such as densities, fluxes, flows, currents are associated with many quantities. Sometimes different terms such as current density and flux density, rate, frequency and current, are used interchangeably in the same context, sometimes they are used uniquely.
To clarify these effective template derived quantities, we let q be any quantity within some scope of context (not necessarily base quantities) and present in the table below some of the most commonly used symbols where applicable, their definitions, usage, SI units and SI dimensions  where [q] denotes the dimension of q.
For time derivatives, specific, molar, and flux densities of quantities there is no one symbol, nomenclature depends on the subject, though time derivatives can be generally written using overdot notation. For generality we use q_{m}, q_{n}, and F respectively. No symbol is necessarily required for the gradient of a scalar field, since only the nabla/del operator ? or grad needs to be written. For spatial density, current, current density and flux, the notations are common from one context to another, differing only by a change in subscripts.
For current density, is a unit vector in the direction of flow, i.e. tangent to a flowline. Notice the dot product with the unit normal for a surface, since the amount of current passing through the surface is reduced when the current is not normal to the area. Only the current passing perpendicular to the surface contributes to the current passing through the surface, no current passes in the (tangential) plane of the surface.
The calculus notations below can be used synonymously.
If X is a nvariable function , then
Differential The differential nspace volume element is ,
Quantity  Typical symbols  Definition  Meaning, usage  Dimension 

Quantity  q  q  Amount of a property  [q] 
Rate of change of quantity, Time derivative  Rate of change of property with respect to time  [q]T^{1}  
Quantity spatial density  ? = volume density (n = 3), ? = surface density (n = 2), ? = linear density (n = 1)
No common symbol for nspace density, here ?_{n} is used. 
Amount of property per unit nspace (length, area, volume or higher dimensions) 
[q]L^{n}  
Specific quantity  q_{m}  Amount of property per unit mass  [q]M^{1}  
Molar quantity  q_{n}  Amount of property per mole of substance  [q]N^{1}  
Quantity gradient (if q is a scalar field).  Rate of change of property with respect to position  [q]L^{1}  
Spectral quantity (for EM waves)  q_{v}, q_{?}, q_{?}  Two definitions are used, for frequency and wavelength:

Amount of property per unit wavelength or frequency.  [q]L^{1} (q_{?}) [q]T (q_{?}) 
Flux, flow (synonymous)  ?_{F}, F  Two definitions are used; 
Flow of a property though a crosssection/surface boundary.  [q]T^{1}L^{2}, [F]L^{2} 
Flux density  F  Flow of a property though a crosssection/surface boundary per unit crosssection/surface area  [F]  
Current  i, I  Rate of flow of property through a cross
section / surface boundary 
[q]T^{1}  
Current density (sometimes called flux density in transport mechanics)  j, J  Rate of flow of property per unit crosssection/surface area  [q]T^{1}L^{2}  
Moment of quantity  m, M  Two definitions can be used; q is a scalar: 
Quantity at position r has a moment about a point or axes, often relates to tendency of rotation or potential energy.  [q]L 
The meaning of the term physical quantity is generally well understood (everyone understands what is meant by the frequency of a periodic phenomenon, or the resistance of an electric wire). The term physical quantity does not imply a physically invariant quantity. Length for example is a physical quantity, yet it is variant under coordinate change in special and general relativity. The notion of physical quantities is so basic and intuitive in the realm of science, that it does not need to be explicitly spelled out or even mentioned. It is universally understood that scientists will (more often than not) deal with quantitative data, as opposed to qualitative data. Explicit mention and discussion of physical quantities is not part of any standard science program, and is more suited for a philosophy of science or philosophy program.
The notion of physical quantities is seldom used in physics, nor is it part of the standard physics vernacular. The idea is often misleading, as its name implies "a quantity that can be physically measured", yet is often incorrectly used to mean a physical invariant. Due to the rich complexity of physics, many different fields possess different physical invariants. There is no known physical invariant sacred in all possible fields of physics. Energy, space, momentum, torque, position, and length (just to name a few) are all found to be experimentally variant in some particular scale and system. Additionally, the notion that it is possible to measure "physical quantities" comes into question, particularly in quantum field theory and normalization techniques. As infinities are produced by the theory, the actual "measurements" made are not really those of the physical universe (as we cannot measure infinities), they are those of the renormalization scheme which is expressly dependent on our measurement scheme, coordinate system and metric system.