Gibbs state: Difference between revisions

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In probability theory and statistical mechanics, a Gibbs state is an equilibrium probability distribution which remains invariant under future evolution of the system. For example, a stationary or steady-state distribution of a Markov chain, such as that achieved by running a Markov chain Monte Carlo iteration for a sufficiently long time, is a Gibbs state.

Precisely, suppose $L$ is a generator of evolutions for an initial state $\rho _{0}$ , so that the state at any later time is given by $\rho (t)=e^{Lt}[\rho _{0}]$ . Then the condition for $\rho _{\infty }$ to be a Gibbs state is

L[\rho _{\infty }]=0

.

In physics there may be several physically distinct Gibbs states in which a system may be trapped, particularly at lower temperatures.

They are named after Josiah Willard Gibbs, for his work in determining equilibrium properties of statistical ensembles. Gibbs himself referred to this type of statistical ensemble as being in "statistical equilibrium".^[1]

References

^ Gibbs, Josiah Willard (1902). Elementary Principles in Statistical Mechanics, developed with especial reference to the rational foundation of thermodynamics. New York: Charles Scribner's Sons.

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[gibbs-1] Gibbs, Josiah Willard (1902). Elementary Principles in Statistical Mechanics, developed with especial reference to the rational foundation of thermodynamics. New York: Charles Scribner's Sons.

[1]

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-In [[probability theory]] and [[statistical mechanics]], a '''Gibbs state''' is an equilibrium probability distribution which remains invariant under future evolution of the system.  For example, a stationary or steady-state distribution of a [[Markov chain]], such as that achieved by running a [[Markov chain Monte Carlo]] iteration for a sufficiently long time, is a Gibbs state.
+In [[probability theory]] and [[statistical mechanics]], a '''Gibbs state''' is an equilibrium [[probability distribution]] which remains invariant under future evolution of the system.  For example, a stationary or steady-state distribution of a [[Markov chain]], such as that achieved by running a [[Markov chain Monte Carlo]] iteration for a sufficiently long time, is a Gibbs state.
-Precisely, suppose <math>L \;</math> is a generator of evolutions for an initial state <math>\rho_0 \;</math>, so that the state at any later time is given by <math>\rho(t) = e^{L t} [\rho_0] \;</math>.  Then the condition for <math>\rho_{\infty} \;</math> to be a Gibbs state is
+Precisely, suppose <math>L </math> is a [[Generator (mathematics)|generator]] of evolutions for an initial state <math>\rho_0 </math>, so that the state at any later time is given by <math>\rho(t) = e^{L t} [\rho_0] </math>.  Then the condition for <math>\rho_{\infty} </math> to be a Gibbs state is
 :<math>L [\rho_{\infty}] = 0 </math> .
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 In [[physics]] there may be several physically distinct Gibbs states in which a system may be trapped, particularly at lower temperatures.
 They are named after [[Josiah Willard Gibbs]], for his work in determining equilibrium properties of [[statistical ensemble]]s. Gibbs himself referred to this type of statistical ensemble as being in "statistical equilibrium".<ref name="gibbs">{{cite book |last=Gibbs |first=Josiah Willard |authorlink=Josiah Willard Gibbs |title=[[Elementary Principles in Statistical Mechanics|Elementary Principles in Statistical Mechanics, developed with especial reference to the rational foundation of thermodynamics]] |year=1902 |publisher=[[Charles Scribner's Sons]] |location=New York}}</ref>
 == See also ==
 * [[Gibbs algorithm]]
 * [[Gibbs measure]]
+* [[KMS state]]
 ==References==
 {{Reflist}}
-{{mathapplied-stub}}
 [[Category:Statistical mechanics]]
 [[Category:Stochastic processes]]
+{{statisticalmechanics-stub}}
+{{mathapplied-stub}}