Quantum machines based on $\mathrm{Cu}_{3}$-like compounds using the Heisenberg antiferromagnetic model in a triangular ring
- URL: http://arxiv.org/abs/2406.01340v1
- Date: Mon, 3 Jun 2024 14:04:01 GMT
- Title: Quantum machines based on $\mathrm{Cu}_{3}$-like compounds using the Heisenberg antiferromagnetic model in a triangular ring
- Authors: Onofre Rojas, Moises Rojas,
- Abstract summary: We present a theoretical investigation into an antiferromagnetically coupled spin system, specifically $textCu_3-textX(textX=As, Sb)$.
This system is modeled using the Heisenberg model within a triangular structure, incorporating exchange interaction, Dzyaloshinskii-Moriya interaction, g-factors, and an external magnetic field.
We explore three quantum machines based on the $textCu_3$-like antiferromagnetically coupled spin system.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: In this work, we present a theoretical investigation into an antiferromagnetically coupled spin system, specifically $\text{Cu}_{3}-\text{X}(\text{X=As, Sb})$, which exhibits a configuration of a slightly distorted equilateral triangle, as identified in previous literature. This system is modeled using the Heisenberg model within a triangular structure, incorporating exchange interaction, Dzyaloshinskii-Moriya interaction, g-factors, and an external magnetic field. We explore three quantum machines based on the $\text{Cu}_{3}$-like antiferromagnetically coupled spin system. The magnetocaloric effect (MCE), which is notably more significant at low temperatures, around $T\sim1$K, for a perpendicular magnetic field at approximately $\sim5$T, has been analyzed. We examine the Carnot machine, observing the influence of the external magnetic field on its operation as both a heat engine and refrigerator, and discuss the thermal efficiencies under these conditions. Our findings suggest that enhanced MCE allows for broader operation regions as a heat engine. Additionally, we explore the quantum Otto machine, showing its versatility in functioning as a heat engine, refrigerator, heater, and thermal accelerator. However, it mainly operates as a refrigerator and accelerator. We also explore their corresponding thermal efficiencies. Similarly, we have analyzed the quantum Stirling machine, which is capable of functioning as a heat engine, refrigerator, heater, and thermal accelerator, but it mainly operates as a refrigerator and thermal accelerator. We also examined the corresponding thermal efficiencies. It is worth mentioning that the Otto machine performance as a heat engine is notably influenced by the MCE, while the operational mode of the Stirling machine switches between a heat engine and accelerator around MCE is more prominent.
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