Quantum machines using Cu3-like compounds modeled by Heisenberg antiferromagnetic in a triangular ring

Abstract

A theoretical study of an antiferromagnetically coupled spin system, specifically Cu3-X (X=As, Sb), characterized by a slightly distorted equilateral triangle configuration is presented. Using the Heisenberg model with exchange and Dzyaloshinskii-Moriya interactions, g-factors, and an external magnetic field, three quantum machines are investigated using this system as the working substance, assuming reversible processes. For Cu3-X he magnetocaloric effect (MCE) is significant at low temperatures (around 1K) under a perpendicular magnetic field (5T). Although only the Cu3-As compound is considered, since the Cu3-Sb compound behaves quite similarly. How MCE influences the Carnot machine, which operates as a heat engine or refrigerator when varying the external magnetic field is analyzed. In contrast, the Otto and Stirling machines can operate as heat engines, refrigerators, heaters, or thermal accelerators, depending on the magnetic field intensity. The results indicate that enhanced MCE broadens the operating regions for these machines, with the Otto and Stirling machines primarily functioning as refrigerators and accelerators. The corresponding thermal efficiencies are also discussed for all operating modes.