Obtaining efficient collisional engines via velocity-dependent drivings

Iago N. Mamede, Angel L. L. Stable, Carlos E. Fiore

Type: Article

Publication Date: 2022-12-19

Citations: 4

DOI: https://doi.org/10.1103/physreve.106.064125

Abstract

Brownian particles interacting sequentially with distinct temperatures and driving forces at each stroke have been tackled as a reliable alternative for the construction of engine setups. However, they can behave very inefficiently depending on the driving used for the work source and/or when temperatures of each stage are very different from each other. Inspired by some models for molecular motors and recent experimental studies, a coupling between driving and velocities is introduced and detail investigated from stochastic thermodynamics. Exact expressions for thermodynamic quantities and distinct maximization routes have been obtained. The search of an optimal coupling provides a substantial increase of engine performance (mainly efficiency), even for large ΔT. A simple and general argument for the optimal coupling can be estimated, irrespective of the driving and other model details.

Locations

Physical review. E - View
arXiv (Cornell University) - View - PDF
PubMed - View

Similar Works

Action	Title	Year	Authors
+	Obtaining efficient collisional engines via velocity dependent drivings	2022	Iago N. Mamede Angel L. L. Stable C. E. Fiore
+ PDF Chat	Thermodynamics and efficiency of sequentially collisional Brownian particles: The role of drivings	2022	Fernando S. Filho Bruno A. N. Akasaki C. E. Fernández Noa Bart Cleuren Carlos E. Fiore
+	Thermodynamics and efficiency of sequentially collisional Brownian particles: The role of drivings	2022	Fernando S. Filho Bruno A. N. Akasaki Carlos E. Fernadéz Noa Bart Cleuren Carlos E. Fiore
+	Efficient asymmetric collisional Brownian particle engines	2021	C. E. Fernández Noa Angel L. L. Stable William G. C. Oropesa Alexandre Rosas C. E. Fiore
+ PDF Chat	Efficient asymmetric collisional Brownian particle engines	2021	C. E. Fernández Noa Angel L. L. Stable William G. C. Oropesa Alexandre Rosas Carlos E. Fiore
+ PDF Chat	Obtaining efficient thermal engines from interacting Brownian particles under time-periodic drivings	2022	Iago N. Mamede Pedro E. Harunari Bruno A. N. Akasaki Karel Proesmans Carlos E. Fiore
+	Obtaining efficient thermal engines from interacting Brownian particles under time dependent periodic drivings.	2021	Iago N. Mamede Pedro E. Harunari Bruno A. N. Akasaki Karel Proesmans Carlos E. Fiore
+ PDF Chat	Thermodynamics of collisional models for Brownian particles: General properties and efficiency	2020	Angel L. L. Stable C. E. Fernández Noa William G. C. Oropesa Carlos E. Fiore
+	Stochastic Heat Engine Using Multiple Interacting Active Particles	2023	Aradhana Kumari Md Samsuzzaman Arnab Saha Sourabh Lahiri
+	Thermodynamics of a minimal collective heat engine: Comparison between engine designs	2023	Felipe Hawthorne Bart Cleuren Carlos E. Fiore
+	Maximum-Power Stirling-like Heat Engine with a Harmonically Confined Brownian Particle	2025	Irene Prieto A. Prados Carlos A. Plata
+ PDF Chat	Maximum power Stirling-like heat engine with a harmonically confined Brownian particle	2024	Irene Prieto-Rodríguez A. Prados Carlos A. Plata
+ PDF Chat	Maximum power operation of interacting molecular motors	2013	N. Golubeva Alberto Imparato
+ PDF Chat	Thermodynamics of underdamped Brownian collisional engines: New insights and resonant phenomena	2024	Gustavo A. L. Forão Fernando S. Filho Bruno A. N. Akasaki Carlos E. Fiore
+	Engineering Ratchet-Based Particle Separation via Shortcuts to Isothermality	2023	Xiuhua Zhao Z. C. Tu Yuhan Ma
+	Driving rapidly while remaining in control: classical shortcuts from Hamiltonian to stochastic dynamics	2022	David Guéry-Odelin Christopher Jarzynski Carlos A. Plata A. Prados Emmanuel Trizac
+ PDF Chat	Driving rapidly while remaining in control: classical shortcuts from Hamiltonian to stochastic dynamics	2022	David Guéry-Odelin Christopher Jarzynski Carlos A. Plata A. Prados Emmanuel Trizac
+ PDF Chat	Designing circle swimmers: Principles and strategies	2021	Zhiyu Cao Huijun Jiang Zhonghuai Hou
+	Carnot, Stirling, Ericsson stochastic heat engines: Efficiency at maximum power	2022	O. Contreras-Vergara N. Sánchez-Salas G. Valencia-Ortega J. I. Jiménez-Aquino
+	Thermodynamics of a collisional quantum-dot machine: the role of stages	2023	C. E. Fernández Noa Carlos E. Fiore F. F. S. Filho Bart Wijns B. Cleuren

Works That Cite This (1)

Action	Title	Year	Authors
+ PDF Chat	Thermodynamics of a collisional quantum-dot machine: the role of stages	2024	Fernando S. Filho C. E. Fernández Noa Carlos E. Fiore Bart Wijns Bart Cleuren

Works Cited by This (23)

Action	Title	Year	Authors
+ PDF Chat	<i>Colloquium</i>: The physics of Maxwell’s demon and information	2009	Koji Maruyama Franco Nori Vlatko Vedral
+ PDF Chat	High-Precision Test of Landauer’s Principle in a Feedback Trap	2014	Yonggun Jun Momčilo Gavrilov John Bechhoefer
+ PDF Chat	Quantum-dot Carnot engine at maximum power	2010	Massimiliano Esposito Ryoichi Kawai Katja Lindenberg Christian Van den Broeck
+ PDF Chat	Self-Motile Colloidal Particles: From Directed Propulsion to Random Walk	2007	Jonathan R. Howse Richard Jones Anthony J. Ryan Tim Gough Reza Vafabakhsh Ramin Golestanian
+ PDF Chat	Stochastic thermodynamics of active Brownian particles	2013	Chandrima Ganguly Debasish Chaudhuri
+ PDF Chat	Single-particle stochastic heat engine	2014	Shubhashis Rana P. S. Pal Arnab Saha A. M. Jayannavar
+ PDF Chat	Thermodynamics of information	2015	Juan M. R. Parrondo Jordan M. Horowitz Takahiro Sagawa
+ PDF Chat	Three faces of the second law. I. Master equation formulation	2010	Massimiliano Esposito Christian Van den Broeck
+ PDF Chat	Stochastic thermodynamics, fluctuation theorems and molecular machines	2012	Udo Seifert
+ PDF Chat	Efficiency at Maximum Power of Interacting Molecular Machines	2012	N. Golubeva Alberto Imparato