image: The left and right parts are new constraints on two types of exotic spin-dependent interactions, as well as limits established by previous experiments. The red line is the upper bound established by our experiment. view more
Credit: ©Science China Press
This study was led by Prof. Jiangfeng Du and Prof. Xing Rong (University of Science and Technology of China). A laboratory search for exotic spin-dependent interactions was conducted with an ensemble-NV-diamond magnetometer. New experimental constraints on two types of exotic interactions are established at the micron scale.
The Standard Model of particle physics cannot explain some of the observational phenomena in current cosmic astronomy, such as dark matter and dark energy. Scientists believe that there may be new particles beyond the Standard Model that could serve as a medium for propagating a new type of exotic spin-dependent interaction. In recent years, the research team has developed the use of quantum sensors in diamonds to precisely measure the exotic interactions, so as to search for possible new particles in the laboratory. In this work, the researchers expanded from a single quantum sensor in diamond to ensemble quantum sensors, greatly improving the detection sensitivity. They realized a laboratory test of exotic spin-dependent interactions between polarized electrons and unpolarized nucleons, and established new experimental constraints at the micrometer scale.
This work demonstrated the unique advantages and potential of diamond quantum precision measurement technology in exploring fundamental physics problems such as new particles and new interactions, and is expected to stimulate extensive interest in cosmology, astrophysics and particle physics.
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See the article:
New Constraints on Exotic Spin-Dependent Interactions with an Ensemble-NV-Diamond Magnetometer
https://doi.org/10.1093/nsr/nwac262
Journal
National Science Review