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CPP: Fachverband Chemische Physik und Polymerphysik

CPP 31: Responsive and Adaptive Polymers

CPP 31.1: Hauptvortrag

Mittwoch, 19. März 2025, 16:15–16:45, H38

Moving with minimum effort – Optimal work protocols for systems with memory — •Sarah Loos¹, Samuel Monter², Felix Ginot², and Clemens Bechinger² — ¹DAMTP, University of Cambridge, UK — ²University of Konstanz

Energy optimization is crucial in engineering and may also govern nonequilibrium processes in chemical and biological systems. Finding optimal solutions for microscale processes–dominated by thermal or nonthermal fluctuations and often displaying memory effects arising from internal degrees of freedom or coupling to viscoelastic environments–posses additional challenges, necessitating general guiding principles. We demonstrate such a general principle for the fundamental problem of dragging a harmonic trap containing a single particle over a finite distance within a given time while minimizing work input. We show that the optimal dragging protocol and the corresponding mean particle trajectory both exhibit time-reversal symmetry, which is a universal and exclusive feature of the optimal solutions. The symmetry principle holds across all media described by a linear generalized Langevin equation, irrespective of the memory kernel or noise properties, including glassy, granular, and active media. For intrinsically driven systems, such as active particles, we show that the optimal protocols remain identical to those for passive systems, but work fluctuations are always increased [2]. [1] S.A.M. Loos, S. Monter, F. Ginot, and C. Bechinger, Phys. Rev. X 14, 021032 (2024). [2] R. Garcia-Millan, J. Schüttler, M.E. Cates, and S.A.M. Loos, ArXiv:2407.18542 (2024).

Keywords: Optimal Control; Non-Markovian processes; Generalized Langevin Equations; Non-equilibrium Soft Matter; Active matter