Closed-loop approach to thermodynamics
Abstract
We present the closed loop approach to linear nonequilibrium thermodynamics considering a generic heat engine dissipatively connected to two temperature baths. The system is usually quite generally characterized by two parameters: the output power and the conversion efficiency , to which we add a third one, the working frequency . We establish that a detailed understanding of the effects of the dissipative coupling on the energy conversion process, necessitates the knowledge of only two quantities: the system's feedback factor and its open-loop gain , the product of which, , characterizes the interplay between the efficiency, the output power and the operating rate of the system. By placing thermodynamics analysis on a higher level of abstraction, the feedback loop approach provides a versatile and economical, hence a very efficient, tool for the study of \emph{any} conversion engine operation for which a feedback factor may be defined.
Cite
@article{arxiv.1606.03387,
title = {Closed-loop approach to thermodynamics},
author = {C. Goupil and H. Ouerdane and E. Herbert and G. Benenti and Y. D'Angelo and Ph. Lecoeur},
journal= {arXiv preprint arXiv:1606.03387},
year = {2016}
}