Using a quantum SWAP engine to experimentally validate thermodynamic uncertainty relations
Abstract
Thermodynamic uncertainty relations (TURs) arise from the bounds on fluctuations of thermodynamics quantities during a non-equilibrium process and they impose constraints on the corresponding process. We experimentally implement a quantum SWAP engine on a nuclear magnetic resonance setup and demonstrate that a Gibbs thermal state can be prepared in two different ways, either directly from a thermal equilibrium state, or by first initializing the system in a pseudopure state. We show that the quantum SWAP engine can work both as a heat engine and as a refrigerator. Starting from a pseudopure state, we construct the SWAP engine, and investigate the violation of two different TURs, namely a generalized TUR and a tighter, more specific TUR. Our results validate that the generalized TUR is obeyed in all the working regimes of the SWAP engine, while the tighter TUR is violated in certain regimes. ~
Cite
@article{arxiv.2410.16230,
title = {Using a quantum SWAP engine to experimentally validate thermodynamic uncertainty relations},
author = {Krishna Shende and Arvind and Kavita Dorai},
journal= {arXiv preprint arXiv:2410.16230},
year = {2024}
}
Comments
9 pages, 7 figures