Study of a low power dissipation,miniature laser-pumped rubidium frequency standard 被引量：1

Study of a low power dissipation,miniature laser-pumped rubidium frequency standard

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摘要 This paper studies a miniature low power consumption laser-pumped atom vapour cell clock scheme. Pumping ^87Rb with a vertical cavity surface emitting laser diode pump and locking the laser frequency on a Doppler-broadened spectral line, it records a 5 × 10^-11τ-1/2 （τ〈500 s） frequency stability with a table-top system in a primary experiment. The study reveals that the evaluated scheme is at the level of 2.7 watts power consumption, 90 cm^3 volume and 10^-12τ-1/2 short-term frequency stability. This paper studies a miniature low power consumption laser-pumped atom vapour cell clock scheme. Pumping ^87Rb with a vertical cavity surface emitting laser diode pump and locking the laser frequency on a Doppler-broadened spectral line, it records a 5 × 10^-11τ-1/2 （τ〈500 s） frequency stability with a table-top system in a primary experiment. The study reveals that the evaluated scheme is at the level of 2.7 watts power consumption, 90 cm^3 volume and 10^-12τ-1/2 short-term frequency stability.

作者刘国宾赵峰顾思洪

机构地区 Wuhan Institute of Physics and Mathematics Graduate School

出处《Chinese Physics B》 SCIE EI CAS CSCD 2009年第9期3839-3843,共5页 中国物理B（英文版）

基金 supported by National Natural Science Foundation of China (Grant Nos 10574141 and 10675162)

关键词 laser-pumped atom clock laser frequency stabilization rubidium vapour cell clock laser-pumped atom clock, laser frequency stabilization, rubidium vapour cell clock

分类号 O562 [理学—原子与分子物理]

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Chinese Physics B

2009年第9期

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Study of a low power dissipation,miniature laser-pumped rubidium frequency standard 被引量：1

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