Information Engine Fueled by First-Passage Times

Aubin Archambault; Caroline Crauste-Thibierge; Alberto Imparato; Christopher Jarzynski; Sergio Ciliberto; Ludovic Bellon

doi:10.1103/s9kj-lczm

Information Engine Fueled by First-Passage Times

Aubin Archambault
, Caroline Crauste-Thibierge
, Alberto Imparato
, Christopher Jarzynski
, Sergio Ciliberto
, Ludovic Bellon

Laboratoire de Physique
University of Trieste
INFN Sezione di Trieste
University of Maryland

Research output: Contribution to journal › Article › peer-review

Abstract

Using a mechanical cantilever submitted to electrostatic feedback control, we investigate the thermodynamic properties of an information engine that extracts work from thermal fluctuations. The cantilever position is rapidly sampled and the feedback is triggered by the first passage of the system across a fixed threshold. The information ΔI associated with the feedback is based on the first-passage-time distribution. In this setting, we derive and experimentally verify two distinct fluctuation theorems that involve ΔI and give a tight bound on the work produced by the engine. Our results extend beyond the specific application to our experiment: we develop a general framework for obtaining fluctuation theorems and work bounds, formulated in terms of probability distributions of protocols rather than underlying measurement outcomes.

Original language	English
Article number	147101
Journal	Physical Review Letters
Volume	135
Issue number	14
DOIs	https://doi.org/10.1103/s9kj-lczm
Publication status	Published - 3 Oct 2025
Externally published	Yes

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abstract = "Using a mechanical cantilever submitted to electrostatic feedback control, we investigate the thermodynamic properties of an information engine that extracts work from thermal fluctuations. The cantilever position is rapidly sampled and the feedback is triggered by the first passage of the system across a fixed threshold. The information ΔI associated with the feedback is based on the first-passage-time distribution. In this setting, we derive and experimentally verify two distinct fluctuation theorems that involve ΔI and give a tight bound on the work produced by the engine. Our results extend beyond the specific application to our experiment: we develop a general framework for obtaining fluctuation theorems and work bounds, formulated in terms of probability distributions of protocols rather than underlying measurement outcomes.",

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AU - Archambault, Aubin

AU - Crauste-Thibierge, Caroline

AU - Imparato, Alberto

AU - Jarzynski, Christopher

AU - Ciliberto, Sergio

AU - Bellon, Ludovic

PY - 2025/10/3

Y1 - 2025/10/3

N2 - Using a mechanical cantilever submitted to electrostatic feedback control, we investigate the thermodynamic properties of an information engine that extracts work from thermal fluctuations. The cantilever position is rapidly sampled and the feedback is triggered by the first passage of the system across a fixed threshold. The information ΔI associated with the feedback is based on the first-passage-time distribution. In this setting, we derive and experimentally verify two distinct fluctuation theorems that involve ΔI and give a tight bound on the work produced by the engine. Our results extend beyond the specific application to our experiment: we develop a general framework for obtaining fluctuation theorems and work bounds, formulated in terms of probability distributions of protocols rather than underlying measurement outcomes.

AB - Using a mechanical cantilever submitted to electrostatic feedback control, we investigate the thermodynamic properties of an information engine that extracts work from thermal fluctuations. The cantilever position is rapidly sampled and the feedback is triggered by the first passage of the system across a fixed threshold. The information ΔI associated with the feedback is based on the first-passage-time distribution. In this setting, we derive and experimentally verify two distinct fluctuation theorems that involve ΔI and give a tight bound on the work produced by the engine. Our results extend beyond the specific application to our experiment: we develop a general framework for obtaining fluctuation theorems and work bounds, formulated in terms of probability distributions of protocols rather than underlying measurement outcomes.

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JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Information Engine Fueled by First-Passage Times

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