Chen, Y.; Guo, R.; Wang, J.; Yu, M.; Zhao, M.; Zhao, L. Theoretical Study on Performing Movement-Related MEG with 83Kr-Based Atomic Comagnetometer. Photonics2023, 10, 1302.
Chen, Y.; Guo, R.; Wang, J.; Yu, M.; Zhao, M.; Zhao, L. Theoretical Study on Performing Movement-Related MEG with 83Kr-Based Atomic Comagnetometer. Photonics 2023, 10, 1302.
Chen, Y.; Guo, R.; Wang, J.; Yu, M.; Zhao, M.; Zhao, L. Theoretical Study on Performing Movement-Related MEG with 83Kr-Based Atomic Comagnetometer. Photonics2023, 10, 1302.
Chen, Y.; Guo, R.; Wang, J.; Yu, M.; Zhao, M.; Zhao, L. Theoretical Study on Performing Movement-Related MEG with 83Kr-Based Atomic Comagnetometer. Photonics 2023, 10, 1302.
Abstract
K-Rb-83Kr based atomic co-magnetometer for measuring moving MEGs is theoretically studied in this paper. Parameters such as the spin exchange rates, the spin dephasing rates and the polarization of the nuclear spins are studied to configure the co-magnetometer. Results show that the nuclear spin could generate around 700 nT magnetic field under which the nuclear spin could compensate wide range of magnetic fields. We also showed the hybrid optical pumping vapor cell fabrication process in this paper. Alkali metals were mixed in a glove box and then was connected to the alkali vapor cell fabrication system. The vapor cell fabrication process is illustrated in this paper.
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