Remote Detection Optical Magnetometry

Alexander M. Akulshin,Dmitry Budker,Felipe Pedreros Bustos,Tong Dang,Emmanuel Klinger,Simon M. Rochester,Arne Wickenbrock,Rui Zhang

Physics Reports（2025）

Optical Sciences Centre | Department of Physics | European Southern Observatory | Johannes Gutenberg-Universität | Rochester Scientific LLC.

Cited 0|Views17

Abstract

Sensitive magnetometers have been applied in a wide range of research fields, including geophysical exploration, bio-magnetic field detection, ultralow-field nuclear magnetic resonance, etc. Commonly, magnetometers are directly placed at the position where the magnetic field is to be measured. However, in some situations, for example in near space or harsh environments, near nuclear reactors or particle accelerators, it is hard to place a magnetometer directly there. If the magnetic field can be detected remotely, i.e., via stand-off detection, this problem can be solved. As optical magnetometers are based on optical readout, they are naturally promising for stand-off detection. We review various approaches to optical stand-off magnetometry proposed and developed over the years, culminating in recent results on measuring magnetic fields in the mesosphere using laser guide stars, magnetometry with mirrorless-lasing readout, and proposals for satellite-assisted interrogation of atmospheric sodium.

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Key words

Remote detection,Magnetometry,Optically pumped magnetometers,Laser guide stars,Mirrorless lasing,Mesospheric sodium

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