Abstract
An equilibrium system which is perturbed by an external potential relaxes to a new equilibrium state, a process obeying the fluctuation-dissipation theorem. In contrast, perturbing by nonconservative forces yields a nonequilibrium steady state, and the fluctuation-dissipation theorem can in general not be applied. Here we exploit a freedom inherent to linear response theory: Force fields which perform work that does not couple statistically to the considered observable can be added without changing the response. Using this freedom, we demonstrate that the fluctuation-dissipation theorem can be applied for certain nonconservative forces. We discuss the case of a nonconservative force field linear in particle coordinates, where the mentioned freedom can be formulated in terms of symmetries. In particular, for the case of shear, this yields a response formula, which we find advantageous over the known Green-Kubo relation in terms of statistical accuracy.
Highlights
The linear response of a classical equilibrium system to a potential perturbation U ptb applied for time t > 0 is given by the fluctuation-dissipation theorem (FDT) [1,2,3,4], A(t ) ptb − A = − 1 [ AU ptb − A(t )U ptb(0) ], (1) kBT where A is an observable of interest, kB is Boltzmann’s constant, T is temperature, and · · · ptb and · · · indicate averages in the perturbed and equilibrium system, respectively
We demonstrate that the fluctuation-dissipation theorem can be applied for certain nonconservative forces
We discuss the case of a nonconservative force field linear in particle coordinates, where the mentioned freedom can be formulated in terms of symmetries
Summary
We discuss the case of a nonconservative force field linear in particle coordinates, where the mentioned freedom can be formulated in terms of symmetries. For the case of shear, this yields a response formula, which we find advantageous over the known Green-Kubo relation in terms of statistical accuracy.
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