KT (energy): Difference between revisions
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All that's in here will be nicely covered by Atkins, I think. Feel free to come up with more specific requests for sources if you can't find it in there |
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{{Lowercase|title=''kT'' (energy)}} |
{{Lowercase|title=''kT'' (energy)}} |
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'''''kT''''' is the product of the [[Boltzmann constant]], ''k'', and the [[temperature]], ''T''. This product is used in [[physics]] as a scaling factor for [[energy]] values in [[molecule|molecular]]-scale systems (sometimes it is used as a unit of energy), as the rates and frequencies of many processes and phenomena depend not on their energy alone, but on the ratio of that energy and ''kT'', that is, on ''E'' / ''kT'' (see [[Arrhenius equation]], [[Boltzmann factor]]). For a system in equilibrium in [[canonical ensemble]], the probability of the system being in state with energy E is given by e<sup>-ΔE / kT</sup>. More fundamentally, ''kT'' is the amount of [[heat]] required to increase the thermodynamic [[entropy]] of a system, in natural units, by one [[Nat (information)|nat]]. |
'''''kT''''' is the product of the [[Boltzmann constant]], ''k'', and the [[temperature]], ''T''. This product is used in [[physics]] as a scaling factor for [[energy]] values in [[molecule|molecular]]-scale systems (sometimes it is used as a unit of energy), as the rates and frequencies of many processes and phenomena depend not on their energy alone, but on the ratio of that energy and ''kT'', that is, on ''E'' / ''kT'' (see [[Arrhenius equation]], [[Boltzmann factor]]). For a system in equilibrium in [[canonical ensemble]], the probability of the system being in state with energy E is given by e<sup>-ΔE / kT</sup>. More fundamentally, ''kT'' is the amount of [[heat]] required to increase the thermodynamic [[entropy]] of a system, in natural units, by one [[Nat (information)|nat]]. |
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Revision as of 14:03, 5 May 2012
kT is the product of the Boltzmann constant, k, and the temperature, T. This product is used in physics as a scaling factor for energy values in molecular-scale systems (sometimes it is used as a unit of energy), as the rates and frequencies of many processes and phenomena depend not on their energy alone, but on the ratio of that energy and kT, that is, on E / kT (see Arrhenius equation, Boltzmann factor). For a system in equilibrium in canonical ensemble, the probability of the system being in state with energy E is given by e-ΔE / kT. More fundamentally, kT is the amount of heat required to increase the thermodynamic entropy of a system, in natural units, by one nat.
In macroscopic scale systems, with large numbers of molecules, RT value is commonly used; its SI units are joules per mole (J/mol): (RT = kT * NA). At room temperature 25 °C (77 °F, 298 K) 1kT is equivalent to 4.11x10−21 J , 4.11 pN·nm , 9.83x10−22 cal, 0.0256 eV, 2.479 kJ·mol−1 or 0.593 kcal·mol−1.
References
- Atkins' Physical Chemistry, 9th ed., by P. Atkins and J. dePaula, Oxford University Press