Extensive quantity
In thermodynamics and materials science, the physical properties of substances are often described as intensive or extensive, a classification that relates to the dependency of the properties upon the size or extent of the system or object in question.
The distinction is based on the concept that smaller, noninteracting identical subdivisions of the system may be identified so that the property of interest does or does not change when the system is divided, or combined.
An intensive property is a bulk property, meaning that it is a physical property of a system that does not depend on the system size or the amount of material in the system. Examples of intensive properties are the temperature and the hardness of an object. No matter how small a diamond is cut, it maintains its intrinsic hardness.
By contrast, an extensive property is one that is additive for independent, noninteracting subsystems.^{[1]} The property is proportional to the amount of material in the system. For example, both the mass and the volume of a diamond are directly proportional to the amount that is left after cutting it from the raw mineral. Mass and volume are extensive properties, but hardness is intensive.
The ratio of two extensive properties, such as mass and volume, is scaleinvariant, and this ratio, the density, is hence an intensive property.
This terminology of intensive and extensive properties was introduced by Richard C. Tolman in 1917.^{[2]}
Contents
Intensive properties
An intensive property is a physical quantity whose value does not depend on the amount of the substance for which it is measured. For example, the temperature of a system in thermal equilibrium is the same as the temperature of any part of it. If the system is divided the temperature of each subsystem is identical. The same applies to the density of a homogeneous system; if the system is divided in half, the mass and the volume change in the identical ratio and the density remains unchanged. Additionally, the boiling point of a substance is another example of an intensive property. For example, the boiling point for water is 100°C at a pressure of one atmosphere, a fact which remains true regardless of quantity.
According to the state postulate, for a sufficiently simple system, only two independent intensive variables are needed to fully specify the entire state of a system. Other intensive properties can be derived from the two known values.
Some intensive properties, such as viscosity, are empirical macroscopic quantities and are not relevant to extremely small systems.
Combined intensive properties
There are four properties in any thermodynamic system, two are intensive and two are extensive.
If the set of parameters, $\backslash \{a\_i\backslash \}$, are intensive properties and another set, $\backslash \{A\_j\backslash \}$, are extensive properties, then the function $F(\backslash \{a\_i\backslash \},\backslash \{A\_j\backslash \})$ is an intensive property if for all $\backslash alpha$,
 $F(\backslash \{a\_i\backslash \},\backslash \{\backslash alpha\; A\_j\backslash \})\; =\; F(\backslash \{a\_i\backslash \},\backslash \{A\_j\backslash \}).\backslash ,$
It follows, for example, that the ratio of two extensive properties is an intensive property  density (intensive) is equal to mass (extensive) divided by volume (extensive).
Examples
Examples of intensive properties include:
 chemical potential
 density (or specific gravity)
 viscosity
 electrical resistivity
 spectral absorption maxima (in solution)
 specific energy
 specific heat capacity
 hardness
 melting point and boiling point
 pressure
 ductility
 elasticity
 malleability
 magnetization
 magnetic field
 concentration
 temperature
 specific volume
Extensive properties
An extensive property is defined by the IUPAC Green Book as a physical quantity which is the sum of the properties of separate noninteracting subsystems that compose the entire system.^{[1]} The value of such an additive property is proportional to the size of the system it describes, or to the quantity of matter in the system. Taking on the example of melting ice, the amount of heat required to melt ice is an extensive property. The amount of heat required to melt one ice cube would be much less than the amount of heat required to melt an iceberg, so it is dependent on the quantity.
Extensive properties are the counterparts of intensive properties, which are intrinsic to a particular subsystem. Dividing one type of extensive property by a different type of extensive property will in general give an intensive value. For example, mass (extensive) divided by volume (extensive) gives density (intensive).
Combined extensive properties
If a set of parameters $\backslash \{a\_i\backslash \}$ are intensive properties and another set $\backslash \{A\_j\backslash \}$ are extensive properties, then the function $F(\backslash \{a\_i\backslash \},\backslash \{A\_j\backslash \})$ is an extensive property if for all $\backslash alpha$,
 $F(\backslash \{a\_i\backslash \},\backslash \{\backslash alpha\; A\_j\backslash \})=\backslash alpha\; F(\backslash \{a\_i\backslash \},\backslash \{A\_j\backslash \}).\backslash ,$
Thus, extensive properties are homogeneous functions (of degree 1) with respect to $\backslash \{A\_j\backslash \}$. It follows from Euler's homogeneous function theorem that
 $F(\backslash \{a\_i\backslash \},\backslash \{A\_i\backslash \})=\backslash sum\_j\; A\_j\; \backslash left(\backslash frac\{\backslash partial\; F\}\{\backslash partial\; A\_j\}\backslash right),$
where the partial derivative is taken with all parameters constant except $A\_j$. The converse is also true  any function which obeys the above relationship will be extensive.
Examples
Examples of extensive properties include:
Related extensive and intensive properties
Thermodynamics  

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Although not true for all physical properties, some properties have corresponding extensive and intensive analogs, many of which are thermodynamic properties. Examples of such extensive thermodynamic properties, that are dependent on the size of the thermodynamic system in question, include volume, internal energy, enthalpy, entropy, Gibbs free energy, Helmholtz free energy, and heat capacity (in the sense of thermal mass). The symbols of these extensive thermodynamic properties shown here are capital letters.
For homogeneous substances, these extensive thermodynamic properties each have corresponding intensive thermodynamic properties, which are expressed on a per mass or volume basis. The name is usually prefixed with the adjective specific to indicate that they are bulk properties, valid at any location (smaller subdivision) in a thermodynamic system. They may be dependent on other conditions at any point, such as temperature, pressure, and material composition, but are not considered dependent on the size of a thermodynamic system or on the amount of material in the system.
Specific volume is volume per mass, the reciprocal of density which equals mass per volume.
Extensive property 
Symbol  SI units  Intensive property** 
Symbol  SI units 

Volume  
Specific volume***  

Internal energy  
Specific internal energy  

Entropy  
Specific entropy  

Enthalpy  
Specific enthalpy  

Gibbs free energy  
Specific Gibbs free energy  

Heat capacity at constant volume 

Specific heat capacity at constant volume 


Heat capacity at constant pressure 

Specific heat capacity at constant pressure 

 * L = liter, J = joule
 ** specific properties, expressed on a per mass basis
 *** Specific volume is the reciprocal of density.
If a molecular weight can be assigned for the substance, or the amount of substance (in moles) can be determined, then each of these thermodynamic properties may be expressed on a molar basis, and their name may be qualified with the adjective molar, yielding terms such as molar volume, molar internal energy, molar enthalpy, molar entropy. Standards for the symbols of molar quantities do not exist. A well known molar volume is that of an ideal gas at standard conditions for temperature and pressure, with the value 22.41liters/mol. Molar Gibbs free energy is commonly referred to as chemical potential, symbolized by μ, particularly when discussing a partial molar Gibbs free energy μ_{i} for a component i in a mixture.
Generality of classification
The general validity of the division of physical properties into extensive and intensive kinds has been addressed in the course of science.^{[2]}^{[3]} The two categories are not allinclusive and some welldefined physical properties conform to neither definition, including mathematical functions such as the square of volume^{[3]} or the square root of volume.^{[2]} This class of functions has no special name and is generally excluded from consideration in thermodynamics.
Redlich also pointed out that the assignment of some properties as intensive or extensive may depend on the way in which subsystems are arranged. For example, if two identical galvanic cells are connected in parallel, the voltage of the system is equal to the voltage of each cell, while the electric charge transferred (or the electric current) is extensive.^{[2]} However if the same cells are connected in series, the charge becomes intensive and the voltage extensive.^{[2]} The IUPAC definitions do not consider such cases.^{[1]}
References
el:Εκτατική μεταβλητή hu:Intenzív mennyiség nl:Extensieve grootheid no:Intensive og ekstensive egenskaper nn:Intensiv eigenskap pl:Zmienna ekstensywna pt:Propriedades extensivas ru:Интенсивная величина sl:Ekstenzivna količina uk:Інтенсивна величина