A generalized fluctuation-response relation is found for thermal systems driven out of equilibrium. Its derivation is independent of many details of the dynamics, which is only required to be firstorder. The result gives a correction to the equilibrium fluctuation-dissipation theorem, in terms of the correlation between observable and excess in dynamical activity caused by the perturbation. Previous approaches to this problem are recovered and extended in a unifying scheme.PACS numbers: 05.70. Ln, The fluctuation-dissipation theorem is a standard chapter in statistical mechanics [1,2,3]. A system in thermal equilibrium has statistical fluctuations proportional to its response to external perturbations: a small impulse changing the potential U → U − h s V at time s, will produce a response R eq QV (t, s) = δ Q(t) /δh s in a quantity Q at time t ≥ s of the formwhere V (s) Q(t) eq is a correlation function quantifying the equilibrium fluctuations in absence of any perturbation, and the proportionality constant β = 1/k B T is the inverse temperature. An early example of this theorem is present in Einstein's treatment of Brownian motion, where the diffusion constant, expressed as a velocity autocorrelation function, is found proportional to the mobility. Other famous examples include the JohnsonNyquist formula for electronic white noise and the Onsager reciprocity for linear response coefficients. So far, approaches deriving a fluctuation-dissipation relation (FDR) for nonequilibrium [4,5,6,7,8,9,10,11,12,13] have not found a physical unification and do not appear as textbook material. One reason may be that previous work has not been seen to identify a sufficiently general structure with a clear corresponding statistical thermodynamic interpretation. Today, such an interpretation has become available from advances in dynamical fluctuation theory for nonequilibrium systems.Aiming to provide a simple and general approach to FDRs, in this Letter we put forward a FDR for nonequilibrium regimes in a framework that may represent a unifying scheme for previous formulations. Our main result can be found in a general formula, Eq. (6) below, which can also sometimes be rewritten as (7) or (11).In order to go beyond equilibrium and beyond formal perturbation theory, it is important to recognize in the right-hand side of (1) the role of entropy production, as usual governing close-to-equilibrium considerations. Eq. (1) expresses the correlation between the dissipation represented by entropy production (energy change divided by temperature) and the observable Q(t). Here, for perturbations of a nonequilibrium system (that has already a non-vanishing set of flows and hence a non-zero entropy production) we will rather speak of the excess of entropy produced by the perturbation h s V .The second ingredient that is essential in nonequilibrium is still a less known quantity, called traffic [14] or dynamical activity [15], first introduced in [16]. Perhaps activity has been somewhat overlooked in the past because it plays a truly sign...
