基于光生自旋相关自由基对的量子传感分子量子比特

IF 6.1 Q2 CHEMISTRY, PHYSICAL Chemical physics reviews Pub Date : 2022-06-01 DOI:10.1063/5.0084072
Tomoyasu Mani
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引用次数: 13

摘要

电子给体-桥-受体(D-B-A)分子中光生自旋相关自由基对(SCRPs)可以作为分子量子比特和固有自旋量子比特对。SCRPs可以采用单重态和三重态自旋,构成量子叠加态。它们的合成可及性和定义良好的结构,以及它们在最初纯净、纠缠自旋态和光学寻址状态下制备的能力,使它们成为推进量子信息科学的有前途的途径之一。两个自旋态之间的相干性和自旋选择性电子转移反应构成了将SCRPs用作传感量子比特的基础。我们可以利用scps的自旋动力学对外部磁场的独特灵敏度,用于传感应用,包括分辨率增强成像,磁力计和磁开关。分子量子传感器,如果实现,可以提供新的技术发展超越可能与传统同行。几十年来,自旋化学学界一直在积极研究磁场对scps化学反应的影响,但我们还没有充分利用分子体系的合成可调性。本文对基于光生scrps的量子传感分子量子比特进行了介绍,旨在为该领域的新手奠定基础,并为活跃在该领域的研究人员提供基础参考。我们重点介绍了构建基于SCRPs的分子量子位所必需的基本原理,以及迄今为止从实验家的角度探索的量子传感实例。
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Molecular qubits based on photogenerated spin-correlated radical pairs for quantum sensing
Photogenerated spin-correlated radical pairs (SCRPs) in electron donor–bridge–acceptor (D–B–A) molecules can act as molecular qubits and inherently spin qubit pairs. SCRPs can take singlet and triplet spin states, comprising the quantum superposition state. Their synthetic accessibility and well-defined structures, together with their ability to be prepared in an initially pure, entangled spin state and optical addressability, make them one of the promising avenues for advancing quantum information science. Coherence between two spin states and spin selective electron transfer reactions form the foundation of using SCRPs as qubits for sensing. We can exploit the unique sensitivity of the spin dynamics of SCRPs to external magnetic fields for sensing applications including resolution-enhanced imaging, magnetometers, and magnetic switch. Molecular quantum sensors, if realized, can provide new technological developments beyond what is possible with classical counterparts. While the community of spin chemistry has actively investigated magnetic field effects on chemical reactions via SCRPs for several decades, we have not yet fully exploited the synthetic tunability of molecular systems to our advantage. This review offers an introduction to the photogenerated SCRPs-based molecular qubits for quantum sensing, aiming to lay the foundation for researchers new to the field and provide a basic reference for researchers active in the field. We focus on the basic principles necessary to construct molecular qubits based on SCRPs and the examples in quantum sensing explored to date from the perspective of the experimentalist.
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