Stochastic control in microscopic nonequilibrium systems

TL;DR

This paper develops a theoretical framework to quantify the energetic costs of stochastic, nonequilibrium control protocols in microscopic systems, providing bounds on work and insights into efficient operation.

Contribution

It generalizes linear-response theory to include stochastic control protocols, deriving bounds on work at finite durations for autonomous microscopic systems.

Findings

Derived a lower bound on work for stochastic protocols

Confirmed theoretical results with model system simulations

Provides thermodynamic insights into rapid microscopic operation

Abstract

Quantifying energy flows at nanometer scales promises to guide future research in a variety of disciplines, from microscopic control and manipulation, to autonomously operating molecular machines. A general understanding of the thermodynamic costs of nonequilibrium processes would illuminate the design principles for efficient microscopic machines. Considerable effort has gone into finding and classifying the deterministic control protocols that drive a system rapidly between states at minimum energetic cost. But for autonomous microscopic systems, driving processes are themselves stochastic. Here we generalize a linear-response framework to incorporate such protocol variability, deriving a lower bound on the work that is realized at finite protocol duration, far from the quasistatic limit. Our findings are confirmed in model systems. This theory provides a thermodynamic rationale for rapid operation, independent of functional incentives.