Yanay Florshaim, Elad Zohar, David Zeev Koplovich, Ilan Meltzer, Rafi Weill, Jonathan Nemirovsky, Amir Stern, Yoav Sagi
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引用次数: 0
摘要
物质波的相干操纵是量子力学的显著特征,也是现代量子技术的基础。空间绝热穿越(SAP)就是这种现象的典型例子,通过调整隧道耦合到中间第三模式的反直觉序列,波包在两个未耦合的局部模式之间转移。虽然这一概念早在二十多年前就已提出,但其观测以前仅限于电磁波。在这项研究中,我们利用在三个微型光学陷阱("光学镊子")之间隧穿的大质量粒子演示了这种量子干涉效应。我们首先在一个陷阱的低振动特征状态下制备超冷费米子原子,然后操纵陷阱之间的距离来执行 SAP 协议。我们观察到原子在两个外阱之间平稳、高效地转移,而留在中央阱中的原子数量极少。这些发现为光学镊子阵列平台的先进控制方案提供了可能性。
Spatial adiabatic passage of ultracold atoms in optical tweezers
Coherent manipulation of matter waves, a distinctive hallmark of quantum mechanics, is fundamental to modern quantum technologies. Spatial adiabatic passage (SAP) is a prime example of this phenomenon, where a wave packet is transferred between two uncoupled localized modes by adjusting the tunneling coupling to an intermediate third mode in a counterintuitive sequence. Although this concept was introduced over two decades ago, its observation was previously limited to electromagnetic waves. In this study, we demonstrate this quantum interference effect using massive particles that tunnel between three micro-optical traps (“optical tweezers”). We begin by preparing ultracold fermionic atoms in low vibrational eigenstates of one trap, followed by manipulating the distance between the traps to execute the SAP protocol. We observe a smooth and high-efficiency transfer of atoms between the two outer traps, with a very low population remaining in the central trap. These findings open possibilities for advanced control schemes in optical tweezer array platforms.
期刊介绍:
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