Mesoscopic quantum thermo-mechanics: A new frontier of experimental physics

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY AVS quantum science Pub Date : 2022-04-20 DOI:10.1116/5.0086059
E. Collin
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引用次数: 3

Abstract

In the last decade, experimentalists have demonstrated their impressive ability to control mechanical modes within mesoscopic objects down to the quantum level: it is now possible to create mechanical Fock states, to entangle mechanical modes from distinct objects, and to store quantum information or transfer it from one quantum bit to another, among the many possibilities found in today's literature. Indeed, mechanics is quantum, very much like spins or electromagnetic degrees of freedom; and all of this is, in particular, referred to as a new engineering resource for quantum technologies. However, there is also much more beyond this utilitarian aspect: invoking the original discussions of Braginsky and Caves, where a quantum oscillator is thought of as a quantum detector for a classical field, namely, a gravitational wave, which is also a unique sensing capability for quantum fields. The subject of study is then the baths to which the mechanical mode is coupled to, let them be known or unknown in nature. This Perspective is about this new potentiality that addresses stochastic thermodynamics, potentially down to its quantum version, the search for a fundamental underlying (random) field postulated in recent theories that can be affiliated to the class of the wave-function collapse models, and more generally open questions of condensed matter like the actual nature of the elusive (and ubiquitous) two-level systems present within all mechanical objects. However, such research turns out to be much more demanding than the use of a few quantum mechanical modes: all the known baths have to be identified, experiments have to be conducted in-equilibrium, and the word “mechanics” needs to be justified by a real ability to move substantially the center-of-mass when a proper drive tone is applied to the system.
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介观量子热力学:实验物理学的新前沿
在过去的十年里,实验者已经证明了他们控制介观物体内机械模式到量子水平的令人印象深刻的能力:现在可以创建机械Fock态,纠缠不同物体的机械模式,并存储量子信息或将其从一个量子位传输到另一个量子点,在当今文学中发现的许多可能性中。事实上,力学是量子的,非常像自旋或电磁自由度;所有这些,尤其被称为量子技术的新工程资源。然而,除了这一实用性方面之外,还有更多的东西:援引Braginsky和Caves最初的讨论,量子振荡器被认为是经典场的量子探测器,即引力波,这也是量子场独特的传感能力。然后研究的主题是与机械模式耦合的浴缸,让它们在自然界中为人所知或未知。这一观点是关于这种新的潜力,它解决了随机热力学,可能一直到它的量子版本,即寻找最新理论中假设的基本的(随机)场,该场可以属于波函数坍缩模型,以及更普遍的关于凝聚态的开放性问题,比如存在于所有机械物体中的难以捉摸(和普遍存在)的二能级系统的实际性质。然而,事实证明,这样的研究比使用几种量子力学模式要求更高:所有已知的浴都必须被识别,实验必须在平衡状态下进行,当对系统施加适当的驱动音调时,“力学”一词需要通过实质上移动质心的真正能力来证明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
9.90
自引率
0.00%
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0
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