Autonomous Engines Driven by Active Matter: Energetics and Design Principles

Pietzonka, Patrick; Fodor, Étienne; Lohrmann, Christoph; Cates, Michael E.; Seifert, Udo

doi:10.1103/physrevx.9.041032

Cited by 129 publications

(121 citation statements)

References 99 publications

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“…Since the work of self-driven particles of Viscek et al 15 , the modeling of active agents has been possible following a series of rules for particle interactions, such as alignment, polarization, repulsion, and quorum-sensing 13 , 16 . These interactions often give rise to the understanding of unexpected phenomena such as collective motion, turbulence, giant fluctuations, rectification, and self-organization 16 – 20 , and at the same time, they reproduce what we observe in nature. At the micro-scale, agents can be modeled as active Brownian particles (ABP), where ABP can take up energy from the environment to store it in an internal depot and convert it internal energy into kinetic energy and motion 21 .…”

Section: Introductionsupporting

confidence: 67%

Understanding contagion dynamics through microscopic processes in active Brownian particles

Norambuena¹,

Valencia²,

Guzmán-Lastra³

2020

Sci Rep

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Together with the universally recognized SIR model, several approaches have been employed to understand the contagion dynamics of interacting particles. Here, Active Brownian particles (ABP) are introduced to model the contagion dynamics of living agents that perform a horizontal transmission of an infectious disease in space and time. By performing an ensemble average description of the ABP simulations, we statistically describe susceptible, infected, and recovered groups in terms of particle densities, activity, contagious rates, and random recovery times. Our results show that ABP reproduces the time dependence observed in traditional compartmental models such as the Susceptible-Infected-Recovery (SIR) models and allows us to explore the critical densities and the contagious radius that facilitates the virus spread. Furthermore, we derive a first-principles analytical expression for the contagion rate in terms of microscopic parameters, without considering free parameters as the classical SIR-based models. This approach offers a novel alternative to incorporate microscopic processes into analyzing SIR-based models with applications in a wide range of biological systems.

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Section: Introductionsupporting

confidence: 67%

Understanding contagion dynamics through microscopic processes in active Brownian particles

Norambuena¹,

Valencia²,

Guzmán-Lastra³

2020

Sci Rep

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“…Recent works have shown that, in nonequilibrium dynamics, the current fluctuations are bounded by the coarse-grained entropy production rate [37][38][39][40][41]. In active fluids, there is no average current of particles provided that no asymmetric external potential is applied [68][69][70]. Yet, the bound on current fluctuations can still be formulated within the mapping of section 3.…”

Section: Efficiency and Transportmentioning

confidence: 99%

Dissipation controls transport and phase transitions in active fluids: mobility, diffusion and biased ensembles

Fodor¹,

Nemoto²,

Vaikuntanathan³

2020

New J. Phys.

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Active fluids operate by constantly dissipating energy at the particle level to perform a directed motion, yielding dynamics and phases without any equilibrium equivalent. The emerging behaviors have been studied extensively, yet deciphering how local energy fluxes control the collective phenomena is still largely an open challenge. We provide generic relations between the activity-induced dissipation and the transport properties of an internal tracer. By exploiting a mapping between active fluctuations and disordered driving, our results reveal how the local dissipation, at the basis of self-propulsion, constrains internal transport by reducing the mobility and the diffusion of particles. Then, we employ techniques of large deviations to investigate how interactions are affected when varying dissipation. This leads us to shed light on a microscopic mechanism to promote clustering at low dissipation, and we also show the existence of collective motion at high dissipation. Overall, these results illustrate how tuning dissipation provides an alternative route to phase transitions in active fluids.

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“…Stochastic thermodynamics has progressively evolved into an essential tool in the study of non-equilibrium systems as it connects the quantities of interest in traditional thermodynamics, such as work, heat and entropy, to the properties of microscopically resolved fluctuating trajectories [ 1 , 2 , 3 ]. The possibility of equipping stochastic processes with a consistent thermodynamic and information-theoretic interpretation has resulted in a number of fascinating works, with the interface between mathematical physics and the biological sciences proving to be a particularly fertile ground for new insights (e.g., [ 4 , 5 , 6 , 7 , 8 ]). The fact that most of the applications live on the small scale is not surprising, since it is precisely at the microscopic scale that fluctuations start to play a non-negligible role.…”

Section: Introductionmentioning

confidence: 99%

Entropy Production in Exactly Solvable Systems

Cocconi

Garcia-Millan

Zhen

et al. 2020

Entropy

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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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Autonomous Engines Driven by Active Matter: Energetics and Design Principles

Cited by 129 publications

References 99 publications

Understanding contagion dynamics through microscopic processes in active Brownian particles

Understanding contagion dynamics through microscopic processes in active Brownian particles

Dissipation controls transport and phase transitions in active fluids: mobility, diffusion and biased ensembles

Entropy Production in Exactly Solvable Systems

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