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Optically enhanced discharge excitation and trapping of $^{39}Ar$

We report on a two-fold increase of the $^{39}Ar$ loading rate in an atom trap by enhancing the generation of metastable atoms in a discharge source. Additional atoms in the metastable $1s_5$ level (Paschen notation) are obtained via optically pumping both the $1s_4$ - $2p_6$ transition at 801 nm and the $1s_2$ - $2p_6$ transition at 923 nm. By solving the master equation for the corresponding six-level system, we identify these two transitions to be the most suitable ones and encounter a transfer process between $1s_2$ and $1s_4$ when pumping both transitions simultaneously. We calculate the previously unknown frequency shifts of the two transitions in $^{39}Ar$ and confirm the results with trap loading measurements. The demonstrated increase in the loading rate enables a corresponding decrease in the required sample size, uncertainty and measurement time for $^{39}Ar$ dating, a significant improvement for applications such as dating of ocean water and alpine ice cores.

preprint2022arXivOpen access
Y. -Q. ChuZ. -F. WanF. RitterbuschW. -K. HuJ. -Q. GuS. -M. HuZ. -H. JiaW. JiangZ. -T. LuL. -T. SunA. -M. TongJ. S. WangG. -M. Yang
physics.atom-ph
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Open access13 authors1 topic
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Y. -Q. ChuZ. -F. WanF. RitterbuschW. -K. HuJ. -Q. GuS. -M. HuZ. -H. JiaW. JiangZ. -T. LuL. -T. SunA. -M. TongJ. S. WangG. -M. Yang

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