Long-lived entanglement of molecules in magic-wavelength optical tweezers

IF 50.5 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Nature Pub Date : 2025-01-15 DOI:10.1038/s41586-024-08365-1

Daniel K. Ruttley, Tom R. Hepworth, Alexander Guttridge, Simon L. Cornish

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Abstract

Realizing quantum control and entanglement of particles is crucial for advancing both quantum technologies and fundamental science. Substantial developments in this domain have been achieved in a variety of systems1–5. In this context, ultracold polar molecules offer new and unique opportunities because of their more complex internal structure associated with vibration and rotation, coupled with the existence of long-range interactions6,7. However, the same properties make molecules highly sensitive to their environment8–10, affecting their coherence and utility in some applications. Here we show that by engineering an exceptionally controlled environment using rotationally magic11,12 optical tweezers, we can achieve long-lived entanglement between pairs of molecules using detectable hertz-scale interactions. We prepare two-molecule Bell states with fidelity $$0.92{4}_{-0.016}^{+0.013}$$ , limited by detectable leakage errors. When correcting for these errors, the fidelity is $$0.97{6}_{-0.016}^{+0.014}$$ . We show that the second-scale entanglement lifetimes are limited solely by these errors, providing opportunities for research in quantum-enhanced metrology7,13, ultracold chemistry14 and the use of rotational states in quantum simulation, quantum computation and as quantum memories. The extension of precise quantum control to complex molecular systems will enable their additional degrees of freedom to be exploited across many domains of quantum science15–17. By engineering an exceptionally controlled environment using rotationally magic optical tweezers, long-lived entanglement between pairs of molecules using detectable hertz-scale interactions can be achieved.

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神奇波长光镊中分子的长期纠缠

实现粒子的量子控制和纠缠对于推进量子技术和基础科学的发展至关重要。这一领域的重大发展已经在各种系统中取得了进展1,2,3,4,5。在这种情况下，超冷极性分子提供了新的和独特的机会，因为它们具有与振动和旋转相关的更复杂的内部结构，再加上存在远程相互作用6,7。然而，相同的性质使分子对环境高度敏感8,9,10，影响了它们在某些应用中的相干性和实用性。在这里，我们展示了通过使用旋转神奇的光学镊子来设计一个特别可控的环境，我们可以利用可探测的赫兹尺度相互作用来实现分子对之间的长期纠缠。我们制备了保真度为$0.92{4}_{-0.016}^{+0.013}$的双分子贝尔态，但受可检测泄漏误差的限制。当修正这些错误时，保真度为$0.97{6}_{-0.016}^{+0.014}$。我们发现二阶纠缠寿命仅受这些误差的限制，这为量子增强计量学7,13、超冷化学以及在量子模拟、量子计算和量子记忆中使用旋转态的研究提供了机会。将精确的量子控制扩展到复杂的分子系统将使其额外的自由度能够在量子科学的许多领域中得到利用15,16,17。

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来源期刊

Nature 综合性期刊-综合性期刊

CiteScore

90.00

自引率

1.20%

发文量

3652

审稿时长

3 months

期刊介绍： Nature is a prestigious international journal that publishes peer-reviewed research in various scientific and technological fields. The selection of articles is based on criteria such as originality, importance, interdisciplinary relevance, timeliness, accessibility, elegance, and surprising conclusions. In addition to showcasing significant scientific advances, Nature delivers rapid, authoritative, insightful news, and interpretation of current and upcoming trends impacting science, scientists, and the broader public. The journal serves a dual purpose: firstly, to promptly share noteworthy scientific advances and foster discussions among scientists, and secondly, to ensure the swift dissemination of scientific results globally, emphasizing their significance for knowledge, culture, and daily life.