# Optical simulation of a quantum thermal machine

**Authors:** M. H. M. Passos, Alan C. Santos, Marcelo S. Sarandy, J. A. O. Huguenin

arXiv: 1812.10102 · 2019-08-13

## TL;DR

This paper presents a novel all-optical simulation of a quantum thermal engine using a single photon to encode the working substance and reservoirs, enabling experimental study of quantum thermodynamics processes.

## Contribution

It introduces a new optical scheme for simulating quantum thermal machines, combining theoretical design with experimental realization using laser beams.

## Key findings

- Successful experimental simulation of an Otto cycle with photons.
- Analysis of quantum friction related to temperature differences.
- Feasibility of optical quantum thermodynamics simulations.

## Abstract

We introduce both a theoretical and an experimental scheme for simulating a quantum thermal engine through an all-optical approach, with the behavior of the working substance and the thermal reservoirs implemented via internal degrees of freedom of a single photon. By using the polarization and propagation path, we encode two quantum bits and then implement the thermodynamical steps of an Otto cycle. To illustrate the feasibility of our proposal, we experimentally realize such simulation through an intense laser beam, evaluating heat and work at each individual step of the thermodynamical cycle. In addition, from the analysis of the entropy production during the entire cycle, we can study the amount of quantum friction produced in the Otto cycle as a function of the difference of temperature between hot and cold reservoirs. Our paper constitutes, therefore, an all-optical-based thermal machine simulation and opens perspectives for other optical simulations in quantum thermodynamics.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1812.10102/full.md

## References

46 references — full list in the complete paper: https://tomesphere.com/paper/1812.10102/full.md

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Source: https://tomesphere.com/paper/1812.10102