Zigan Zhen scite author profile

The rate of entropy production by a stochastic process quantifies how far it is from thermodynamic equilibrium. Equivalently, entropy production captures the degree to which global detailed balance and time-reversal symmetry are broken. Despite abundant references to entropy production in the literature and its many applications in the study of non-equilibrium stochastic particle systems, a comprehensive list of typical examples illustrating the fundamentals of entropy production is lacking. Here, we present a brief, self-contained review of entropy production and calculate it from first principles in a catalogue of exactly solvable setups, encompassing both discrete- and continuous-state Markov processes, as well as single- and multiple-particle systems. The examples covered in this work provide a stepping stone for further studies on entropy production of more complex systems, such as many-particle active matter, as well as a benchmark for the development of alternative mathematical formalisms.

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Optimal Ratchet Potentials for Run-and-Tumble particles

Zhen¹,

Pruessner²

2022

Preprint

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Particle entity in the Doi–Peliti and response field formalisms

Bothe

Cocconi

Zhen

et al. 2023

J. Phys. A: Math. Theor.

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We introduce a procedure to test a theory for point particle entity, that is, whether said theory takes into account the discrete nature of the constituents of the system. We then identify the mechanism whereby particle entity is enforced in the context of two ﬁeld-theoretic frameworks designed to incorporate the particle nature of the degrees of freedom, namely the Doi-Peliti ﬁeld theory and the response ﬁeld ﬁeld theory that derives from Dean’s equation. While the Doi-Peliti ﬁeld theory encodes the particle nature at a very fundamental level that is easily revealed, demonstrating the same for Dean’s equation is more involved and results in a number of surprising diagrammatic identities. We derive those and discuss their implications. These results are particularly pertinent in the context of active matter, whose surprising and often counterintuitive phenomenology rests wholly on the particle nature of the agents and their degrees of freedom as particles.

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Particle Entity in the Doi-Peliti and Response Field Formalisms

Bothe¹,

Cocconi²,

Zhen³

et al. 2022

Preprint

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We introduce a procedure to test a theory for point particle entity, that is, whether said theory takes into account the discrete nature of the constituents of the system. We then identify the mechanism whereby particle entity is enforced in the context of two field-theoretic frameworks designed to incorporate the particle nature of the degrees of freedom, namely the Doi-Peliti field theory and the response field theory that derives from Dean's equation. While the Doi-Peliti field theory encodes the particle nature at a very fundamental level that is easily revealed, demonstrating the same for Dean's equation is more involved and results in a number of surprising diagrammatic identities. We derive those and discuss their implications. These results are particularly pertinent in the context of active matter, whose surprising and often counterintuitive phenomenology rests wholly on the particle nature of the agents and their degrees of freedom as particles.

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Run-and-tumble motion in a linear ratchet potential: analytic solution, power extraction and first-passage properties

Roberts¹,

Zhen²

2023

Preprint

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We explore the properties of a system of run-and-tumble (RnT) particles moving in a piecewiselinear "ratchet" potential, and subject to non-negligible diffusion, by deriving exact analytical results for its steady-state probability density, current, entropy production rate, power output, and thermodynamic efficiency. The current, and thus the extractable power and efficiency, have non-monotonic dependencies on the diffusion strength, ratchet height, and particle self-propulsion speed, peaking at finite values in each case. In the case where the particles' self-propulsion is completely suppressed by the force from the ratchet, and thus a current can be generated only by diffusion-mediated barrier crossings, the system's entropy production rate remains finite in the limit of vanishing diffusion. In the final part of this work, we consider RnT motion in a linear ratchet potential on a bounded interval, allowing the derivation of mean first-passage times and splitting probabilities for different boundary and initial conditions. The present work resides at the interface of exactly solvable models of run-and-tumble motion and the study of work extraction from active matter by providing exact expressions pertaining to the feasibility and future design of active engines. Our results are in agreement with Monte Carlo simulations.

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Zigan Zhen

Entropy Production in Exactly Solvable Systems

Optimal Ratchet Potentials for Run-and-Tumble particles

Particle entity in the Doi–Peliti and response field formalisms

Particle Entity in the Doi-Peliti and Response Field Formalisms

Run-and-tumble motion in a linear ratchet potential: analytic solution, power extraction and first-passage properties

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