Efficiency of Brownian heat engines
- 1 June 1999
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review E
- Vol. 59 (6) , R6219-R6222
- https://doi.org/10.1103/physreve.59.r6219
Abstract
We study the efficiency of one-dimensional thermally driven Brownian ratchets or heat engines. We identify and compare the three basic setups characterized by the type of the connection between the Brownian particle and the two heat reservoirs: (i) simultaneous, (ii) alternating in time, and (iii) position dependent. We make a clear distinction between the heat flow via the kinetic and the potential energy of the particle, and show that the former is always irreversible and it is only the third setup where the latter is reversible when the engine works quasistatically. We also show that in the third setup the heat flow via the kinetic energy can be reduced arbitrarily, proving that even for microscopic heat engines there is no fundamental limit of the efficiency lower than that of a Carnot cycle.Keywords
This publication has 17 references indexed in Scilit:
- Efficiency of Brownian motorsEurophysics Letters, 1998
- Energetics of a Forced Thermal RatchetPhysical Review Letters, 1998
- Modeling molecular motorsReviews of Modern Physics, 1997
- Kinetic Characterization of Heat Bath and the Energetics of Thermal Ratchet ModelsJournal of the Physics Society Japan, 1997
- Thermodynamics and Kinetics of a Brownian MotorScience, 1997
- Non-equilibrium directed diffusion and inherently irreversible heat enginesJournal of Physics A: General Physics, 1997
- Criticism of Feynman’s analysis of the ratchet as an engineAmerican Journal of Physics, 1996
- Brownian motors driven by temperature oscillationsPhysics Letters A, 1996
- Biased Brownian motion as the operating principle for microscopic enginesBioelectrochemistry and Bioenergetics, 1996
- Energy transduction between a concentration gradient and an alternating electric fieldThe Journal of Chemical Physics, 1990