Thermodynamics of interacting systems: the role of the topology and collective effects

Iago N. Mamede, Karel Proesmans, Carlos E. Fiore

Published 2023-08-04Version 1

We will study a class of system composed of interacting quantum dots (QDs) placed in contact with a hot and cold thermal baths subjected to a non-conservative driving worksource. Despite their simplicity, these models showcase an intricate array of phenomena, including pump and heat engine regimes as well as a discontinuous phase transition. We will look at three distinctive topologies: a minimal and beyond minimal (homogeneous and heterogeneous interaction structures). The former case is represented by stark different networks ("all-to-all" interactions and only a central interacting to its neighbors) and present exact solutions, whereas homogeneous and heterogeneous structures have been analyzed by numerical simulations. We find that the topology plays a major role on the thermodynamic performance if the individual energies of the quantum dots are small, in part due to the presence of first-order phase-transitions. If the individual energies are large, the topology is not important and results are well-described by a system with all-to-all interactions.