Infrared laser threshold magnetometry with a NV doped diamond intracavity etalon

Yannick Dumeige; Jean François Roch; Fabien Bretenaker; Thierry Debuisschert; Victor Acosta; Christoph Becher; Georgios Chatzidrosos; Arne Wickenbrock; Lykourgos Bougas; Alexander Wilzewski; Dmitry Budker

doi:10.1364/OE.27.001706

Infrared laser threshold magnetometry with a NV doped diamond intracavity etalon

Yannick Dumeige, Jean François Roch, Fabien Bretenaker, Thierry Debuisschert, Victor Acosta, Christoph Becher, Georgios Chatzidrosos, Arne Wickenbrock, Lykourgos Bougas, Alexander Wilzewski, Dmitry Budker

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a hybrid laser system consisting of a semiconductor external cavity laser associated to an intra-cavity diamond etalon doped with nitrogen-vacancy color centers. We consider laser emission tuned to the infrared absorption line that is enhanced under the magnetic field dependent nitrogen-vacancy electron spin resonance and show that this architecture leads to a compact solid-state magnetometer that can be operated at room-temperature. The sensitivity to the magnetic field limited by the photon shot-noise of the output laser beam is estimated to be less than 1 pT/Hz. Unlike usual NV center infrared magnetometry, this method would not require an external frequency stabilized laser. Since the proposed system relies on the competition between the laser threshold and an intracavity absorption, such laser-based optical sensor could be easily adapted to a broad variety of sensing applications based on absorption spectroscopy.

Original language	English
Pages (from-to)	1706-1717
Number of pages	12
Journal	Optics Express
Volume	27
Issue number	2
DOIs	https://doi.org/10.1364/OE.27.001706
Publication status	Published - 21 Jan 2019
Externally published	Yes

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title = "Infrared laser threshold magnetometry with a NV doped diamond intracavity etalon",

abstract = "We propose a hybrid laser system consisting of a semiconductor external cavity laser associated to an intra-cavity diamond etalon doped with nitrogen-vacancy color centers. We consider laser emission tuned to the infrared absorption line that is enhanced under the magnetic field dependent nitrogen-vacancy electron spin resonance and show that this architecture leads to a compact solid-state magnetometer that can be operated at room-temperature. The sensitivity to the magnetic field limited by the photon shot-noise of the output laser beam is estimated to be less than 1 pT/Hz. Unlike usual NV center infrared magnetometry, this method would not require an external frequency stabilized laser. Since the proposed system relies on the competition between the laser threshold and an intracavity absorption, such laser-based optical sensor could be easily adapted to a broad variety of sensing applications based on absorption spectroscopy.",

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T1 - Infrared laser threshold magnetometry with a NV doped diamond intracavity etalon

AU - Dumeige, Yannick

AU - Roch, Jean François

AU - Bretenaker, Fabien

AU - Debuisschert, Thierry

AU - Acosta, Victor

AU - Becher, Christoph

AU - Chatzidrosos, Georgios

AU - Wickenbrock, Arne

AU - Bougas, Lykourgos

AU - Wilzewski, Alexander

AU - Budker, Dmitry

PY - 2019/1/21

Y1 - 2019/1/21

N2 - We propose a hybrid laser system consisting of a semiconductor external cavity laser associated to an intra-cavity diamond etalon doped with nitrogen-vacancy color centers. We consider laser emission tuned to the infrared absorption line that is enhanced under the magnetic field dependent nitrogen-vacancy electron spin resonance and show that this architecture leads to a compact solid-state magnetometer that can be operated at room-temperature. The sensitivity to the magnetic field limited by the photon shot-noise of the output laser beam is estimated to be less than 1 pT/Hz. Unlike usual NV center infrared magnetometry, this method would not require an external frequency stabilized laser. Since the proposed system relies on the competition between the laser threshold and an intracavity absorption, such laser-based optical sensor could be easily adapted to a broad variety of sensing applications based on absorption spectroscopy.

AB - We propose a hybrid laser system consisting of a semiconductor external cavity laser associated to an intra-cavity diamond etalon doped with nitrogen-vacancy color centers. We consider laser emission tuned to the infrared absorption line that is enhanced under the magnetic field dependent nitrogen-vacancy electron spin resonance and show that this architecture leads to a compact solid-state magnetometer that can be operated at room-temperature. The sensitivity to the magnetic field limited by the photon shot-noise of the output laser beam is estimated to be less than 1 pT/Hz. Unlike usual NV center infrared magnetometry, this method would not require an external frequency stabilized laser. Since the proposed system relies on the competition between the laser threshold and an intracavity absorption, such laser-based optical sensor could be easily adapted to a broad variety of sensing applications based on absorption spectroscopy.

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DO - 10.1364/OE.27.001706

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Infrared laser threshold magnetometry with a NV doped diamond intracavity etalon

Abstract

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