Stochastic thermodynamics for delayed Langevin systems

Abstract

Stochastic thermodynamics (ST) for delayed Langevin systems are discussed. By using the general principles of ST, the first-law-like energy balance and trajectory-dependent entropy s(t) can be well-defined in a similar way as that in a system without delay. Since the presence of time delay brings an additional entropy flux into the system, the conventional second law < stot> 0 no longer holds true, where stot denotes the total entropy change along a stochastic path and <...> stands for average over the path ensemble. With the help of a Fokker-Planck description, we introduce a delay-averaged trajectory-dependent dissipation functional η [(t)] which involves the work done by a delay-averaged force F(x,t) along the path (t) and equals to the medium entropy change sm[ x(t)] in the absence of delay. We show that the total dissipation functional R = s + η, where s denotes the system entropy change along a path, obeys < R > 0, which could be viewed as the second law in the delayed system. In addition, the integral fluctuation theorem < <e(-R)>=1 also holds true. We apply these concepts to a linear Langevin system with time delay and periodic external force. Numerical results demonstrate that the total entropy change < stot > could indeed be negative when the delay feedback is positive. By using an inversing-mapping approach, we are able to obtain the delay-averaged force F(x,t) from the stationary distribution and then calculate the functional R as well as its distribution. The second law < R > 0$ and the fluctuation theorem are successfully validated.