Surface and chemical effects on 199Hg spin polarization relaxation in optically pumped magnetometers
Abstract
Quantum spin magnetometry using optically pumped 199Hg has been successfully used in many fundamental physics experiments. A serious problem that has not been resolved is the instability of the 199Hg spin relaxation rate in atomic vapor cells under irradiation with 254 nm Hg resonance light. In this paper, previously obtained data are re-analyzed or analyzed for the first time. The effects of impurities of H2 and O2 are elucidated, and possible ways to stabilize cells are discussed. Surface states originating from the an der Waals interaction of with fused silica are analyzed and shown to be critical to understanding relaxation mechanisms. A discussion of the possible use of a mixture of N2O and other gases is presented.
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