Optimal thermal refrigerator

Abstract

We study a refrigerator model which consists of two n-level systems interacting via a pulsed external field. Each system couples to its own thermal bath at temperatures Th and Tc, respectively (θ Tc/Th<1). The refrigerator functions in two steps: thermally isolated interaction between the systems driven by the external field and isothermal relaxation back to equilibrium. There is a complementarity between the power of heat transfer from the cold bath and the efficiency: the latter nullifies when the former is maximized and vice versa. A reasonable compromise is achieved by optimizing over the inter-system interaction and intra-system energy levels the product of the heat-power and efficiency. The efficiency is then found to be bounded from below by ζ CA=11-θ-1 (an analogue of Curzon-Ahlborn efficiency for refrigerators), besides being bound from above by the Carnot efficiency ζ C = 11-θ-1. The lower bound is reached in the equilibrium limit θ 1, while the Carnot bound is reached (for a finite power and a finite amount of heat transferred per cycle) in the macroscopic limit n 1. The efficiency is exactly equal to ζ CA, when the above optimization is constrained by assuming homogeneous energy spectra for both systems.