On typicality in nonequilibrium steady states
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Evans, Denis J.
Williams, Stephen R.
Searles, Debra J.
Rondoni, Lamberto
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Springer Verlag (Germany)
Abstract
From the statistical mechanical viewpoint, relaxation of macroscopic systems and
response theory rest on a notion of typicality, according towhich the behavior of singlemacroscopic
objects is given by appropriate ensembles: ensemble averages of observable quantities
represent the measurements performed on single objects, because “almost all” objects share
the same fate. In the case of non-dissipative dynamics and relaxation toward equilibrium
states, “almost all” is referred to invariant probability distributions that are absolutely continuous
with respect to the Lebesgue measure. In otherwords, the collection of initialmicro-states
(single systems) that do not follow the ensemble is supposed to constitute a set of vanishing,
phase space volume. This approach is problematic in the case of dissipative dynamics
and relaxation to nonequilibrium steady states, because the relevant invariant distributions
attribute probability 1 to sets of zero volume, while evolution commonly begins in equilibrium
states, i.e., in sets of full phase space volume. We consider the relaxation of classical,
thermostatted particle systems to nonequilibrium steady states. We show that the dynamical
condition known as T-mixing is necessary and sufficient for relaxation of ensemble averages
to steady state values. Moreover, we find that the condition known as weak T-mixing
applied to smooth observables is sufficient for ensemble relaxation to be independent of the initial ensemble. Lastly, we show that weak T-mixing provides a notion of typicality for
dissipative dynamics that is based on the (non-invariant) Lebesgue measure, and that we call
physical ergodicity.
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Journal of Statistical Physics
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Open Access