Spin-bearing molecules as optically addressable platforms for quantum technologies

IF 6.5 2区物理与天体物理 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nanophotonics Pub Date : 2024-10-23 DOI:10.1515/nanoph-2024-0420

Senthil Kuppusamy Kumar, David Hunger, Mario Ruben, Philippe Goldner, Diana Serrano

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Abstract

Efforts to harness quantum hardware relying on quantum mechanical principles have been steadily progressing. The search for novel material platforms that could spur the progress by providing new functionalities for solving the outstanding technological problems is however still active. Any physical property presenting two distinct energy states that can be found in a long-lived superposition state can serve as a quantum bit (qubit), the basic information processing unit in quantum technologies. Molecular systems that can feature electron and/or nuclear spin states together with optical transitions are one of the material platforms that can serve as optically addressable qubits. The attractiveness of molecular systems for quantum technologies relies on the fact that molecular structures of atomically defined nature can be obtained in endless diversity of chemical compositions. Crucially, by harnessing the molecular design protocols, the optical and spin (electronic and nuclear) properties of molecules can be tailored, aiding the design of optically addressable spin qubits and quantum sensors. In this contribution, we present a concise and collective discussion of optically addressable spin-bearing molecules – namely, organic molecules, transition metal (TM) and rare-earth ion (REI) complexes – and highlight recent results such as chemical tuning of optical and electron spin quantum coherence, optical spin initialization and readout, intramolecular quantum teleportation, optical coherent storage, and photonic-enhanced optical addressing. We envision that optically addressable spin-carrying molecules could become a scalable building block of quantum hardware for applications in the fields of quantum sensing, quantum communication and quantum computing.

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作为量子技术光学寻址平台的自旋分子

利用量子力学原理开发量子硬件的工作一直在稳步推进。然而，人们仍在积极寻找新型材料平台，以便通过提供新功能来解决悬而未决的技术问题，从而推动技术进步。任何呈现两种不同能量状态的物理特性，只要能在长期存在的叠加态中找到，都可以作为量子比特（qubit），即量子技术中的基本信息处理单元。具有电子和/或核自旋态以及光跃迁特性的分子系统是可用作光学可寻址量子位的材料平台之一。分子系统对量子技术的吸引力在于，可以通过无穷无尽的化学成分获得原子定义的分子结构。最重要的是，通过利用分子设计方案，可以定制分子的光学和自旋（电子和核）特性，从而有助于设计可光学寻址的自旋量子比特和量子传感器。在本文中，我们将对可光学寻址的自旋分子--即有机分子、过渡金属（TM）和稀土离子（REI）复合物--进行简明扼要的集体讨论，并重点介绍光学和电子自旋量子相干性的化学调整、光学自旋初始化和读出、分子内量子远距传输、光学相干存储和光子增强光学寻址等最新成果。我们设想，可光学寻址的自旋携带分子可以成为量子硬件的可扩展构件，应用于量子传感、量子通信和量子计算领域。

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

Nanophotonics NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

13.50

自引率

6.70%

发文量

358

审稿时长

7 weeks

期刊介绍： Nanophotonics, published in collaboration with Sciencewise, is a prestigious journal that showcases recent international research results, notable advancements in the field, and innovative applications. It is regarded as one of the leading publications in the realm of nanophotonics and encompasses a range of article types including research articles, selectively invited reviews, letters, and perspectives. The journal specifically delves into the study of photon interaction with nano-structures, such as carbon nano-tubes, nano metal particles, nano crystals, semiconductor nano dots, photonic crystals, tissue, and DNA. It offers comprehensive coverage of the most up-to-date discoveries, making it an essential resource for physicists, engineers, and material scientists.