Thermodynamic limits of dynamic cooling

Abstract

We study dynamic cooling, where an externally driven two-level system is cooled via reservoir, a quantum system with initial canonical equilibrium state. We obtain explicitly the minimal possible temperature T min>0 reachable for the two-level system. The minimization goes over all unitary dynamic processes operating on the system and reservoir, and over the reservoir energy spectrum. The minimal work needed to reach T min grows as 1/T min. This work cost can be significantly reduced, though, if one is satisfied by temperatures slightly above T min. Our results on T min>0 prove unattainability of the absolute zero temperature without ambiguities that surround its derivation from the entropic version of the third law. The unattainability can be recovered, albeit via a different mechanism, for cooling by a reservoir with an initially microcanonic state. We also study cooling via a reservoir consisting of N 1 identical spins. Here we show that T min1N and find the maximal cooling compatible with the minimal work determined by the free energy.