We have performed a pure frequency measurement of the 2S-8S/D two-photon transition in atomic hydrogen. The hydrogen frequencies are compared with the difference of two optical standards, the methane-stabilized He-Ne laser and the iodine-stabilized He-Ne laser. In this way, an optical frequency of atomic hydrogen is directly linked for the first time to the caesium clock without any interferometry. We deduce a new value for the Rydberg constant, R(infinity) = 109 737.315 683 4(24) cm(-1) with an uncertainty of 2.2 parts in 10(11). This value is currently the most precise available.
FIRST PURE FREQUENCY-MEASUREMENT OF AN OPTICAL-TRANSITION IN ATOMIC-HYDROGEN - BETTER DETERMINATION OF THE RYDBERG CONSTANT
1993
Abstract
We have performed a pure frequency measurement of the 2S-8S/D two-photon transition in atomic hydrogen. The hydrogen frequencies are compared with the difference of two optical standards, the methane-stabilized He-Ne laser and the iodine-stabilized He-Ne laser. In this way, an optical frequency of atomic hydrogen is directly linked for the first time to the caesium clock without any interferometry. We deduce a new value for the Rydberg constant, R(infinity) = 109 737.315 683 4(24) cm(-1) with an uncertainty of 2.2 parts in 10(11). This value is currently the most precise available.File in questo prodotto:
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