Quantum sensing tools to characterize physical, chemical and biological processes with magnetic resonance

IF 2.624
Analia Zwick, Gonzalo A. Álvarez
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引用次数: 1

Abstract

Nuclear Magnetic Resonance (NMR) plays a central role in developing quantum information sciences and technologies. Key features such as its non-invasive nature and the ability to process information on nuclear spins by versatile quantum control designs with electromagnetic fields, have made NMR to become a powerful technique for sensing systems from atomic and molecular scales with spectroscopy to millimeters in imaging. This brief overview provides quantum sensing tools with which we are contributing from Latin America, by combining quantum dynamical control and estimation strategies with NMR methods to probe physical, chemical, and biological processes. It introduces the basic and key concepts on how controlled spin-sensors can monitor the correlation dynamics of their environment, and selectively and optimally infer its relevant parameters. Then these concepts are illustrated with state-of-the-art implementations for characterizing (i) biological tissue microstructure with diffusion weighting imaging, (ii) quantum information dynamics and scrambling in out-of-equilibrium systems with solid-state NMR quantum simulations, and (iii) molecular structures by selective estimation of spin–spin couplings and online learning control designs with experimental proposals. We expect these concepts will motivate the development of quantum dynamical control of spin sensors to monitor systems in a variety of fields, and in particular to exploit the non-invasive strength of NMR, e.g. in biomedical diagnosis.

Abstract Image

量子传感工具表征物理,化学和生物过程与磁共振
核磁共振(NMR)在发展量子信息科学和技术中起着核心作用。主要特点,如它的非侵入性和处理核自旋信息的能力,通过电磁场的通用量子控制设计,使核磁共振成为一种强大的技术,用于从原子和分子尺度的光谱到毫米成像的传感系统。这篇简短的概述提供了量子传感工具,我们从拉丁美洲贡献,通过将量子动态控制和估计策略与NMR方法相结合来探测物理,化学和生物过程。介绍了受控自旋传感器如何监测环境的相关动态,并有选择地、最优地推断其相关参数的基本概念和关键概念。然后,这些概念通过最先进的实现来说明,用于表征(i)扩散加权成像的生物组织微观结构,(ii)非平衡系统中的量子信息动力学和置乱,以及(iii)通过选择性估计自旋-自旋耦合和在线学习控制设计的分子结构。我们期望这些概念将激发自旋传感器的量子动力学控制的发展,以监测各种领域的系统,特别是利用核磁共振的非侵入性强度,例如在生物医学诊断中。
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来源期刊
CiteScore
1.90
自引率
0.00%
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