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Main Authors: Bu, Jin-Tao, Zhang, Jian-Qi, Ding, Ge-Yi, Li, Jia-Chong, Zhang, Jia-Wei, Wang, Bin, Ding, Wen-Qiang, Yuan, Wen-Fei, Chen, Liang, Zhong, Qi, Keçebaş, Ali, Özdemir, Şahin K., Zhou, Fei, Jing, Hui, Feng, Mang
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.18927
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author Bu, Jin-Tao
Zhang, Jian-Qi
Ding, Ge-Yi
Li, Jia-Chong
Zhang, Jia-Wei
Wang, Bin
Ding, Wen-Qiang
Yuan, Wen-Fei
Chen, Liang
Zhong, Qi
Keçebaş, Ali
Özdemir, Şahin K.
Zhou, Fei
Jing, Hui
Feng, Mang
author_facet Bu, Jin-Tao
Zhang, Jian-Qi
Ding, Ge-Yi
Li, Jia-Chong
Zhang, Jia-Wei
Wang, Bin
Ding, Wen-Qiang
Yuan, Wen-Fei
Chen, Liang
Zhong, Qi
Keçebaş, Ali
Özdemir, Şahin K.
Zhou, Fei
Jing, Hui
Feng, Mang
contents Quantum heat engines and refrigerators are open quantum systems, whose dynamics can be well understood using a non-Hermitian formalism. A prominent feature of non-Hermiticity is the existence of exceptional points (EPs), which has no counterpart in closed quantum systems. It has been shown in classical systems that dynamical encirclement in the vicinity of an EP, whether the loop includes the EP or not, could lead to chiral mode conversion. Here, we show that this is valid also for quantum systems when dynamical encircling is performed in the vicinity of their Liouvillian EPs (LEPs) which include the effects of quantum jumps and associated noise - an important quantum feature not present in previous works. We demonstrate, using a Paul-trapped ultracold ion, the first chiral quantum heating and refrigeration by dynamically encircling a closed loop in the vicinity of an LEP. We witness the cycling direction to be associated with the chirality and heat release (absorption) of the quantum heat engine (quantum refrigerator). Our experiments have revealed that not only the adiabaticity-breakdown but also the Landau-Zener-Stückelberg process play an essential role during dynamic encircling, resulting in chiral thermodynamic cycles. Our observations contributes to further understanding of chiral and topological features in non-Hermitian systems and pave a way to exploring the relation between chirality and quantum thermodynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2405_18927
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Chiral quantum heating and cooling with an optically controlled ion
Bu, Jin-Tao
Zhang, Jian-Qi
Ding, Ge-Yi
Li, Jia-Chong
Zhang, Jia-Wei
Wang, Bin
Ding, Wen-Qiang
Yuan, Wen-Fei
Chen, Liang
Zhong, Qi
Keçebaş, Ali
Özdemir, Şahin K.
Zhou, Fei
Jing, Hui
Feng, Mang
Quantum Physics
Quantum heat engines and refrigerators are open quantum systems, whose dynamics can be well understood using a non-Hermitian formalism. A prominent feature of non-Hermiticity is the existence of exceptional points (EPs), which has no counterpart in closed quantum systems. It has been shown in classical systems that dynamical encirclement in the vicinity of an EP, whether the loop includes the EP or not, could lead to chiral mode conversion. Here, we show that this is valid also for quantum systems when dynamical encircling is performed in the vicinity of their Liouvillian EPs (LEPs) which include the effects of quantum jumps and associated noise - an important quantum feature not present in previous works. We demonstrate, using a Paul-trapped ultracold ion, the first chiral quantum heating and refrigeration by dynamically encircling a closed loop in the vicinity of an LEP. We witness the cycling direction to be associated with the chirality and heat release (absorption) of the quantum heat engine (quantum refrigerator). Our experiments have revealed that not only the adiabaticity-breakdown but also the Landau-Zener-Stückelberg process play an essential role during dynamic encircling, resulting in chiral thermodynamic cycles. Our observations contributes to further understanding of chiral and topological features in non-Hermitian systems and pave a way to exploring the relation between chirality and quantum thermodynamics.
title Chiral quantum heating and cooling with an optically controlled ion
topic Quantum Physics
url https://arxiv.org/abs/2405.18927