Litcius/Paper detail

Irreversibility, heat and information flows induced by non-reciprocal interactions

Sarah A. M. Loos, Sabine H. L. Klapp

2020New Journal of Physics126 citationsDOIOpen Access PDF

Abstract

Abstract We study the thermodynamic properties induced by non-reciprocal interactions between stochastic degrees of freedom in time- and space-continuous systems. We show that, under fairly general conditions, non-reciprocal coupling alone implies a steady energy flow through the system, i.e., non-equilibrium. Projecting out the non-reciprocally coupled degrees of freedom renders non-Markovian, one-variable Langevin descriptions with complex types of memory, for which we find a generalized second law involving information flow. We demonstrate that non-reciprocal linear interactions can be used to engineer non-monotonic memory, which is typical for, e.g., time-delayed feedback control, and is automatically accompanied with a nonzero information flow through the system. Furthermore, already a single non-reciprocally coupled degree of freedom can extract energy from a single heat bath (at isothermal conditions), and can thus be viewed as a minimal version of a time-continuous, autonomous ‘Maxwell demon’. We also show that for appropriate parameter settings, the non-reciprocal system has characteristic features of active matter, such as a positive energy input on the level of the fluctuating trajectories without global particle transport.

Topics & Concepts

PhysicsReciprocalDegrees of freedom (physics and chemistry)Statistical physicsCoupling (piping)Monotonic functionFlow (mathematics)Classical mechanicsSecond law of thermodynamicsEnergy (signal processing)Maxwell's demonMechanicsMathematical analysisThermodynamicsQuantum mechanicsMathematicsLinguisticsMechanical engineeringEngineeringPhilosophyAdvanced Thermodynamics and Statistical Mechanicsstochastic dynamics and bifurcationNeural dynamics and brain function