Related papers: An integrated magnetometry platform with stackable waveguide-assisted detection channels for sensing arrays

An integrated magnetometry platform with stackable waveguide-assisted detection channels for sensing arrays

URL: http://arxiv.org/abs/2012.02560v1
Date: Fri, 4 Dec 2020 12:59:29 GMT
Title: An integrated magnetometry platform with stackable waveguide-assisted detection channels for sensing arrays
Authors: Michael Hoese, Michael K. Koch, Vibhav Bharadwaj, Johannes Lang, John P. Hadden, Reina Yoshizaki, Argyro N. Giakoumaki, Roberta Ramponi, Fedor Jelezko, Shane M. Eaton, Alexander Kubanek
Abstract summary: We present a novel architecture which allows us to create NV$-$-centers a few nanometers below the diamond surface. We experimentally verify the coupling efficiency, showcase the detection of magnetic resonance signals through the waveguides and perform first proof-of-principle experiments in magnetic field and temperature sensing. In the future, our approach will enable the development of two-dimensional sensing arrays facilitating spatially and temporally correlated magnetometry.
Score: 45.82374977939355
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The negatively-charged NV$^-$-center in diamond has shown great success in nanoscale, high-sensitivity magnetometry. Efficient fluorescence detection is crucial for improving the sensitivity. Furthermore, integrated devices enable practicable sensors. Here, we present a novel architecture which allows us to create NV$^-$-centers a few nanometers below the diamond surface, and at the same time in the mode field maximum of femtosecond-laser-written type-II waveguides. We experimentally verify the coupling efficiency, showcase the detection of magnetic resonance signals through the waveguides and perform first proof-of-principle experiments in magnetic field and temperature sensing. The sensing task can be operated via the waveguide without direct light illumination through the sample, which marks an important step for magnetometry in biological systems which are fragile to light. In the future, our approach will enable the development of two-dimensional sensing arrays facilitating spatially and temporally correlated magnetometry.

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