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Main Authors: Bopp, Julian M., Conradi, Hauke, Perona, Felipe, Palaci, Anil, Wollenberg, Jonas, Flisgen, Thomas, Liero, Armin, Christopher, Heike, Keil, Norbert, Knolle, Wolfgang, Knigge, Andrea, Heinrich, Wolfgang, Kleinert, Moritz, Schröder, Tim
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2401.00854
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author Bopp, Julian M.
Conradi, Hauke
Perona, Felipe
Palaci, Anil
Wollenberg, Jonas
Flisgen, Thomas
Liero, Armin
Christopher, Heike
Keil, Norbert
Knolle, Wolfgang
Knigge, Andrea
Heinrich, Wolfgang
Kleinert, Moritz
Schröder, Tim
author_facet Bopp, Julian M.
Conradi, Hauke
Perona, Felipe
Palaci, Anil
Wollenberg, Jonas
Flisgen, Thomas
Liero, Armin
Christopher, Heike
Keil, Norbert
Knolle, Wolfgang
Knigge, Andrea
Heinrich, Wolfgang
Kleinert, Moritz
Schröder, Tim
contents Integrated and fiber-packaged magnetic field sensors with a sensitivity sufficient to sense electric pulses propagating along nerves in life science applications and with a spatial resolution fine enough to resolve their propagation directions will trigger a tremendous step ahead not only in medical diagnostics, but in understanding neural processes. Nitrogen-vacancy centers in diamond represent the leading platform for such sensing tasks under ambient conditions. Current research on uniting a good sensitivity and a high spatial resolution is facilitated by scanning or imaging techniques. However, these techniques employ moving parts or bulky microscope setups. Despite being far developed, both approaches cannot be integrated and fiber-packaged to build a robust, adjustment-free hand-held device. In this work, we introduce novel concepts for spatially resolved magnetic field sensing and 2-D gradiometry with an integrated magnetic field camera. The camera is based on infrared absorption optically detected magnetic resonance (IRA-ODMR) mediated by perpendicularly intersecting infrared and pump laser beams forming a pixel matrix. We demonstrate our 3-by-3 pixel sensor's capability to reconstruct the position of an electromagnet in space. Furthermore, we identify routes to enhance the magnetic field camera's sensitivity and spatial resolution as required for complex sensing applications.
format Preprint
id arxiv_https___arxiv_org_abs_2401_00854
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Diamond-on-chip infrared absorption magnetic field camera
Bopp, Julian M.
Conradi, Hauke
Perona, Felipe
Palaci, Anil
Wollenberg, Jonas
Flisgen, Thomas
Liero, Armin
Christopher, Heike
Keil, Norbert
Knolle, Wolfgang
Knigge, Andrea
Heinrich, Wolfgang
Kleinert, Moritz
Schröder, Tim
Applied Physics
Optics
Quantum Physics
Integrated and fiber-packaged magnetic field sensors with a sensitivity sufficient to sense electric pulses propagating along nerves in life science applications and with a spatial resolution fine enough to resolve their propagation directions will trigger a tremendous step ahead not only in medical diagnostics, but in understanding neural processes. Nitrogen-vacancy centers in diamond represent the leading platform for such sensing tasks under ambient conditions. Current research on uniting a good sensitivity and a high spatial resolution is facilitated by scanning or imaging techniques. However, these techniques employ moving parts or bulky microscope setups. Despite being far developed, both approaches cannot be integrated and fiber-packaged to build a robust, adjustment-free hand-held device. In this work, we introduce novel concepts for spatially resolved magnetic field sensing and 2-D gradiometry with an integrated magnetic field camera. The camera is based on infrared absorption optically detected magnetic resonance (IRA-ODMR) mediated by perpendicularly intersecting infrared and pump laser beams forming a pixel matrix. We demonstrate our 3-by-3 pixel sensor's capability to reconstruct the position of an electromagnet in space. Furthermore, we identify routes to enhance the magnetic field camera's sensitivity and spatial resolution as required for complex sensing applications.
title Diamond-on-chip infrared absorption magnetic field camera
topic Applied Physics
Optics
Quantum Physics
url https://arxiv.org/abs/2401.00854