Efficiency at maximum power of Feynman's ratchet as a heat engine

Abstract

The maximum power of Feynman's ratchet as a heat engine and the corresponding efficiency (η) are investigated by optimizing both the internal parameter and the external load. When a perfect ratchet device (no heat exchange between the ratchet and the paw via kinetic energy) works between two thermal baths at temperatures T1> T2, its efficiency at maximum power is found to be η =ηC2 /[ηC-(1-ηC)(1-ηC)], where ηC 1-T2/T1. This efficiency is slightly higher than the value 1-T2/T1 obtained by Curzon and Ahlborn [Am. J. Phys. 43 (1975) 22] for macroscopic heat engines. It is also slightly larger than the result ηSS 2ηC/(4-ηC) obtained by Schmiedl and Seifert [EPL 81 (2008) 20003] for stochastic heat engines working at small temperature difference, while the evident deviation between η and ηSS appears at large temperature difference. For an imperfect ratchet device in which the heat exchange between the ratchet and the paw via kinetic energy is non-vanishing, the efficiency at maximum power decreases with increasing the heat conductivity.