Roman surface: Difference between revisions

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{{Main|Intensive and extensive properties}}
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{| class="wikitable" style="text-align:center"
|+[[Thermodynamic]] [[physical property|properties]] and their characteristics
!Property!!Symbol!!Units!![[Intensive and extensive properties|Extensive?]]!![[Intensive and extensive properties|Intensive?]]!![[Conjugate variables (thermodynamics)|Conjugate]]!![[Thermodynamic potential|Potential?]]!![[State function|State<br /> qty.]]?!![[Process function|Process<br /> qty.]]?
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|style="text-align:left"|[[activity (chemistry)|Activity]]
|<math>a</math>
|{{spaced ndash}}
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Altitude]]
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|m
|{{aye}}
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|style="text-align:left"|[[Chemical potential]]
|<math>\mu_i</math>
|kJ/mol
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|{{aye}}
|Particle<br /> number <math>N_i</math>
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|{{aye}}
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|style="text-align:left"|[[Compressibility]] <small>(adiabatic)</small>
|<math>\beta_S</math>, <math>\kappa</math>
|Pa<sup>−1</sup>
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Compressibility]] <small>(isothermal)</small>
|<math>\beta_T</math>, <math>\kappa</math>
|Pa<sup>−1</sup>
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|{{aye}}
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|{{aye}}
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|-
|style="text-align:left"|[[Cryoscopic constant]]<ref>{{Citation
  | last = Aylward
  | first = Gordon
  | author-link = Gordon Aylward
  | last2 = Findlay
  | first2 = Tristan
  | author2-link = Tristan Findlay
  | title = SI Chemical Data 5th ed.
  | place = Sweden
  | publisher = John Wiley & Sons
  | year = 2002
  | edition = 5
  | pages = 202
  | isbn = 0-470-80044-5}}</ref>
|<math>K_f</math>
|K·kg/mol
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|style="text-align:left"|[[Density]]
|<math>\rho</math>
|kg/m<sup>3</sup>
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Ebullioscopic constant]]
|<math>K_b</math>
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|style="text-align:left"|[[Enthalpy]]
|<math>H</math>
|J
|{{aye}}
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|{{aye}}
|{{aye}}
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|style="text-align:left"|{{space|3}}↳ [[Specific enthalpy]]
|<math>h</math>
|J/kg
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[thermodynamic entropy|Entropy]]
|<math>S</math>
|J/K
|{{aye}}
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|Temperature <math>T</math>
|{{aye}} <small>([[Free entropy|entropic]])</small>
|{{aye}}
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|style="text-align:left"|{{space|3}}↳ Specific entropy
|<math>s</math>
|J/(kg K)
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Fugacity]]
|<math>f</math>
|N/m²
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Gas constant]]
|<math>R, \bar R</math>
|J/K
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|{{aye}}
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|style="text-align:left"|{{space|3}}↳ [[Specific gas constant]]<br/>{{space|6}}<small>(for a particular substance)</small>
|<math>R_S</math>
|J/(kg K)
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|{{aye}}
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|style="text-align:left"|[[Gibbs free energy]]
|<math>G</math>
|J
|{{aye}}
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|{{aye}}
|{{aye}}
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|style="text-align:left"|{{space|3}}↳ Specific Gibbs free entropy
|<math>g</math>
|J/(kg K)
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Free entropy|Gibbs free entropy]]
|<math>\Xi</math>
|J/K
|{{aye}}
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|{{aye}} <small>([[Free entropy|entropic]])</small>
|{{aye}}
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|-
|style="text-align:left"|[[Grand potential|Grand / Landau potential]]
|<math>\Omega</math>
|J
|{{aye}}
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|{{aye}}
|{{aye}}
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|style="text-align:left"|[[Heat]]
|<math>Q</math>
|J
|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Heat capacity]] <small>(constant pressure)</small>
|<math>C_p</math>
|J/K
|{{aye}}
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|{{aye}}
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|style="text-align:left"|{{space|3}}↳ [[Specific heat capacity]]<br/>{{space|6}}<small>(constant pressure)</small>
|<math>c_p</math>
|J/(kg·K)
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Heat capacity]] <small>(constant volume)</small>
|<math>C_v</math>
|J/K
|{{aye}}
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|{{aye}}
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|-
|style="text-align:left"|{{space|3}}↳ [[Specific heat capacity]]<br/>{{space|6}}<small>(constant volume)</small>
|<math>c_v</math>
|J/(kg·K)
|
|{{aye}}
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|{{aye}}
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|-
|style="text-align:left"|[[Helmholtz free energy]]
|<math>A</math>, <math>F</math>
|J
|{{aye}}
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|{{aye}}
|{{aye}}
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|-
|style="text-align:left"|[[Free entropy|Helmholtz free entropy]]
|<math>\Phi</math>
|J/K
|{{aye}}
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|{{aye}} <small>([[Free entropy|entropic]])</small>
|{{aye}}
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|-
|style="text-align:left"|[[Internal energy]]
|<math>U</math>
|J
|{{aye}}
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|{{aye}}
|{{aye}}
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|style="text-align:left"|{{space|3}}↳ [[Specific internal energy]]
|<math>u</math>
|J/kg
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Internal pressure]]
|<math> \pi _T</math>
|Pa
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Mass]]
|<math>m</math>
|kg
|{{aye}}
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|style="text-align:left"|[[Particle number]]
|<math>N_i</math>
|{{spaced ndash}}
|{{aye}}
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|Chemical<br /> potential <math>\mu_i</math>
|
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|-
|style="text-align:left"|[[Pressure]]
|<math>p</math>
|Pa
|
|{{aye}}
|Volume <math>V</math>
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|{{aye}}
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|-
|style="text-align:left"|[[Thermodynamic temperature|Temperature]]
|<math>T</math>
|K
|
|{{aye}}
|Entropy <math>S</math>
|
|{{aye}}
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|-
|style="text-align:left"|[[Thermal conductivity]]
|<math>k</math>
|W/(m·K)
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Thermal diffusivity]]
|<math>\alpha</math>
|m²/s
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Thermal expansion]] <small>(linear)</small>
|<math>\alpha_L</math>
|K<sup>−1</sup>
|
|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Thermal expansion]] <small>(area)</small>
|<math>\alpha_A</math>
|K<sup>−1</sup>
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Thermal expansion]] <small>(volumetric)</small>
|<math>\alpha_V</math>
|K<sup>−1</sup>
|
|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Vapor quality]]<ref name=boles>{{Cite book  | last1 = Cengel | first1 = Yunus A. | last2 = Boles | first2 = Michael A. | title = Thermodynamics: an engineering approach | year = 2002 | publisher = McGraw-Hill | location = Boston  | isbn = 0-07-121688-X | pages =  79}}</ref>
|<math>\chi</math>
|{{spaced ndash}}
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|{{aye}}
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|{{aye}}
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|style="text-align:left"|[[Volume (thermodynamics)|Volume]]
|<math>V</math>
|m<sup>3</sup>
|{{aye}}
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|Pressure <math>P</math>
|
|{{aye}}
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|-
|style="text-align:left"|{{space|3}}↳ [[Specific volume]]
|<math>v</math>
|m<sup>3</sup>/kg
|
|{{aye}}
|
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|{{aye}}
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|-
|style="text-align:left"|[[Work_(thermodynamics)|Work]]
|<math>W</math>
|J
|{{aye}}
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|{{aye}}
|}
 
Specific properties are expressed on a per mass basis; in some circumstances other dimensions could be used, such as per-mole.
 
==See also==
* [[Dimensionless number]]s
* [[Thermodynamic databases for pure substances]]
* [[Thermodynamic variable]]
 
==References==
{{reflist}}
 
{{DEFAULTSORT:List Of Thermodynamic Properties}}
[[Category:Physics-related lists|Thermodynamic properties]]

Revision as of 02:39, 10 February 2014

No matter how fast you run the animal will catch up and kill you. There is no way these results could be achieved.

Here is my page :: how long does the average man last in bed after penetration (http://prematureejaculationtrainers.com/)

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