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Unveiling synchronization preferences of quantum thermal machines 게시판 상세보기
Title Unveiling synchronization preferences of quantum thermal machines
Embargo date 2023-07-18 17:02 Hits 186
Press release docx 파일명 : [v5] Press_release_Thingna.docx [v5] Press_release_Thingna.docx
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Unveiling synchronization preferences of quantum thermal machines

- Quantum engines and refrigerators not only have differing functions, but they also prefer contrasting synchronization behavior -

Researchers from the Center of Theoretical Physics of Complex Systems within the Institute for Basic Science (PCS-IBS) made an important discovery that describes the relationship between synchronization and thermodynamics in quantum systems.

The question of how order arises from disorder has captivated humanity for centuries. One fascinating example of such emergence is synchronization, where multiple oscillators initialized randomly could end up oscillating in harmony. Synchronization exists in our everyday lives, e.g. the sound of clapping hands or the simultaneous flashing of fireflies. Remarkably, scientists have discovered many instances of synchronization in diverse natural and artificial phenomena, including in very small systems governed by quantum mechanics

At the same time, the study of synchronization must also consider the second law of thermodynamics which only allows the total disorder of the universe to increase. This means that for a spontaneous emergence of order-like synchronization to occur, there has to be a cost of increasing disorder somewhere else, e.g. a wasteful heat in the surrounding environment. Yet, despite these intriguing connections, the precise relationship between synchronization and thermodynamics remains a mystery.

To unravel the underlying connection between synchronization and thermodynamics in the quantum regime, PCS-IBS researchers investigated a novel quantum thermal machine that exhibits synchronization. This machine is capable of acting as a quantum heat engine or as a quantum refrigerator. As a heat engine, it transforms heat flow from hot to cold baths to amplify the intensity of laser light. Conversely, as a refrigerator, it uses energy from laser light to maintain the temperature of the cold bath. Importantly, this machine is able to undergo synchronization simultaneously while performing its task due to its continuous interaction with the laser.

Curiously, the researchers found that as they scaled up the machine, multiple synchronizing actors started to arise within the machine. The synchronization behavior of the machine was not solely influenced by its interaction with lasers but also by the interplay between its various components.

These distinct synchronization actors could both cooperate and compete, much like two individuals jumping on a trampoline – for example, let's call them Jack and Jill. Cooperation arises when both Jack and Jill adjust their jumping rhythm in harmony, reaching their highest and lowest points simultaneously. Conversely, competition occurs when Jack attempts to match Jill’s rhythm while Jill deliberately does the opposite, such as aiming to be at the lowest point when Jack reaches his highest

According to the corresponding author, Dr. Juzar Thingna, “This is the first example in which synchronizing quantum systems are shown to cooperate and compete, opening a path to a richer synchronization landscape like quantum chimeras.”

Intriguingly, the cooperation and competition between different synchronization mechanisms are intimately related to the thermodynamic functionality of the machine. Cooperation manifests in the case of the refrigerator, i.e., they have a preference for a system that synchronizes in harmony, like a peaceful orchestra. On the other hand, competition arises in the case of heat engines, as their components thrive in the middle of a crazy party and use all the chaos to perform at their best.

These findings are important because not only do they shed light on the fundamental relation between synchronization and thermodynamics, but they also give us new ideas for designing quantum technologies and relate the abstract notion of synchronization to the performance of quantum devices. In other words, improving our understanding of how synchronization works in quantum machines, will allow us to make better devices that work coherently together. This could lead to more efficient and powerful quantum machines that will one day ignite the quantum revolution.

Figure 1. (a) Schematic diagram of the quantum thermal machine considered. The red and blue rectangles represent hot and cold baths, the horizontal lines represent the quantum energy levels of the working medium, and the green wavy lines represent laser light. Contrasting synchronization behavior of the system when it acts as an engine (b) and refrigerator (c). In the “chaotic” engine regime the phases are distributed uniformly between [0,2π] whereas in the “calm” refrigerator regime the phases are all localized at 3π/2.
Figure 1. (a) Schematic diagram of the quantum thermal machine considered. The red and blue rectangles represent hot and cold baths, the horizontal lines represent the quantum energy levels of the working medium, and the green wavy lines represent laser light. Contrasting synchronization behavior of the system when it acts as an engine (b) and refrigerator (c). In the “chaotic” engine regime the phases are distributed uniformly between [0,2π] whereas in the “calm” refrigerator regime the phases are all localized at 3π/2.

Notes for editors

- References
Taufiq Murtadho, Sai Vinjanampathy, and Juzar Thingna, “Cooperation and Competition in Synchronous Open Quantum Systems”, Physical Review Letters (2023). Taufiq Murtadho, Juzar Thingna, and Sai Vinjanampathy, “Deriving lower bounds on the efficiency of near-degenerate thermal machines via synchronization”, Physical Review A (2023).


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- About the Institute for Basic Science (IBS)
IBS was founded in 2011 by the government of the Republic of Korea with the sole purpose of driving forward the development of basic science in South Korea. IBS has 6 research institutes and 33 research centers as of July 2023. There are eleven physics, three mathematics, five chemistry, nine life science, two earth science, and three interdisciplinary research centers.

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