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arxiv: 2504.19285 · v2 · pith:QFDRRWI5 · submitted 2025-04-27 · cond-mat.stat-mech · cond-mat.soft

Control of active field theories at minimal dissipation

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classification cond-mat.stat-mech cond-mat.soft
keywords activecontroldissipationdurationprotocolsystemsapproachequilibrium
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Advances in experimental techniques enable the precise manipulation of a large variety of active systems, which constantly dissipate energy to sustain nonequilibrium phenomena without any equilibrium equivalent. To design novel materials out of active systems, an outstanding challenge is to rationalize how material properties can be optimally controlled by applying external perturbations. However, equilibrium thermodynamics is inadequate to guide the control of such nonequilibrium systems. Therefore, there is a dire need for a novel framework to provide a systematic toolbox for the thermodynamic control of active matter. Here, we build an optimization procedure for generic active field theories within a thermodynamically consistent formulation. Central to our approach is the distinction between the protocol heat, which is dissipated only during manipulation, and the total heat, which also accounts for the post-manipulation dissipation. We demonstrate that the latter generically features a global minimum with respect to the protocol duration. We deploy our versatile approach to an active theory of phase separation, and examine the scalings of the optimal protocol duration with respect to activity and system size. Remarkably, we reveal that the landscape of steady-state dissipation regulates the crossover between optimal control strategies for a finite duration.

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Cited by 3 Pith papers

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    Dissipative noisy fluctuations in the controller make finite-time protocols optimal for a Brownian particle in a harmonic trap, with a transition to zero duration at critical fluctuation strength.

  2. Topology of pulsating active matter: Defect asymmetry controls emergent motility

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    Defect asymmetry in pulsating active matter enables emergent motility via a ratchet effect that breaks symmetries and controls a crossover from spiral to fiber-like waves.

  3. Self-propulsion protocols for swift non-equilibrium state transitions and enhanced cooling in active systems

    cond-mat.stat-mech 2026-04 unverdicted novelty 6.0

    Self-propulsion noise statistics define speed limits on non-equilibrium transitions in active matter, with non-stationary initials allowing faster cooling than passive protocols.