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Searching for Exotic Spin-Dependent Interactions with Diamond-Based Vector Magnetometer

Published 23 Feb 2024 in hep-ex | (2402.15042v1)

Abstract: We propose a new method to search for exotic spin-spin interactions between electrons and nucleons using a diamond-based vector magnetometer. The vector magnetometer can be constructed from ensembles of nitrogen-vacancy centers along different axes in a diamond. The ${14}\mathrm{N} $ nuclear spins of nitrogen-vacancy centers in the same diamond can be polarized through the dynamic nuclear polarization method to serve as spin sources. With the vector magnetometer, the sought-after exotic interactions can be distinguished from the magnetic dipole-dipole interaction. For the axion-mediated interaction $ V_{PP} $, new upper bounds of the coupling $ |g_{P}{e} g_{P}{N}| $ are expected within the force range from 10 nm to 100 $ \mu $m. For the $ Z' $-mediated interaction $ V_{AA} $, new upper bounds of the coupling $ |g_{A}{e} g_{A}{N}| $ are expected within the force range from 10 nm to 1 cm. The new upper bounds for $ V_{PP} $ and $ V_{AA} $ are both expected to be more than 5 orders of magnitude more stringent than existing constraints at the force range of 1 $ \mu $m with the total measurement time of one day.

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Authors (4)

  1. Aolong Guo 
  2. Runqi Kang 
  3. Man Jiao 
  4. Xing Rong 

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