双光子吸收碱金属蒸气器研究进展 -

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双光子吸收碱金属蒸气器研究进展

doi:10.3788/CO.20191201.0038

俞航航^{1, 2,},
陈飞^1,,,
李耀彪¹,
何洋¹,
潘其坤¹,
谢冀江¹,
于德洋¹,
卢启鹏¹

1.
中国科学院长春光学精密机械与物理研究所与物质相互作用国家重点实验室光电对抗技术创新研究室, 吉林长春 130033
2.
中国科学院大学, 北京 100049

基金项目:

中科院国防创新基金项目CXJJ-16M228

吉林省中青年科技创新领军人才及团队项目20170519012JH

吉林省重大科技招标专项20160203016GX

详细信息

作者简介:
俞航航(1992-), 男, 山东枣庄人, 博士研究生, 2015年于山东师范大学获得学士学位, 现为中国科学院长春光学精密机械与物理研究所光学工程硕博连读研究生, 主要从事碱金属器方面的研究。E-mail:13021908922@163.com
陈飞(1982—)，男，河南南阳人，副研究员，博士生导师，2011年于哈尔滨工业大学获得硕博士学位，现工作于中国科学院长春光学精密机械与物理研究所与物质相互作用国家重点实验室，主要从事高功率气体器及其应用方面的研究。E-mail:feichenny@126.com

中图分类号:TN248.2
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出版历程
- 收稿日期:2017-10-26
- 修回日期:2017-12-02
- 刊出日期:2019-02-01

Research progress on the two-photon absorption alkali vapor laser

1.
State Key Laboratory of Laser Interaction with Matter, Innovation Laboratory of Electro-Optical Countermeasures Technology, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China
2.
University of Chinese Academy of Sciences, Beijing 100049, China

Funds:

Defense Innovation Fund of Chinese Academy of SciencesCXJJ-16M228

Young and Middle-Aged Science and Technology Innovation Leader and Team Project in Jilin Province20170519012JH

Major Scientific and Technological Bidding in Jilin Province20160203016GX

More Information

Corresponding author:CHEN Fei. E-mail:13021908922@163.com

摘要

摘要:蓝紫和中红外在基础研究和国防工程中有重要的应用前景。单光子吸收的碱金属蒸气器具有量子效率高、受激发射截面大和热管理性能好等优点，近些年来已成为领域中研究热点之一，目前已实现kW量级的输出。双光子吸收的碱金属蒸气器可实现蓝紫和中红外级联输出的特性，也引起越来越多的关注。本文从碱金属原子密度、泵浦光功率、偏振和频率失调量以及调控等几种影响因素出发，综述了双光子吸收碱金属蒸气的研究进展，在此基础上分析了影响输出特性的原因，最后对双光子吸收碱金属蒸气器的发展趋势进行了展望。
- 碱金属蒸气器/
- 双光子吸收/
- 红外/
- 蓝紫
Abstract:Blue-violet lasers and mid-infrared lasers play an important role in the fields of basic research and defense engineering. Single-photon absorption alkali vapor lasers have recently become an area of high interest in laser research for their key advantages, such as high quantum efficiency, large stimulated emission cross-sections and effective thermal management performance. At present, they have achieved an output power reaching 1 kW. Two-photon absorption alkali vapor lasers have attracted increasing attention for their blue-violet laser and mid-infrared laser cascade output characteristics. In this paper, research progress on the two-photon absorption alkali vapor laser is reviewed with regards to alkali atomic density, pump laser power, polarization and frequency offset, controlling laser etc.. The reasons for any influence these factors have on output are then analyzed. Finally, predictions on the future development of the two-photon absorption alkali vapor laser are provided.
- alkali vapor laser/
- two-photon absorption/
- infrared laser/
- blue-violet laser

HTML全文

图 1铷原子单波长泵浦能级跃迁图

Figure 1.Energy level structure of single-wavelength pumped rubidium atom

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图 2铷原子双波长泵浦能级跃迁图

Figure 2.Energy level structure of double-wavelength pumped rubidium atom

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图 3频率失调量对蓝光特性影响实验装置示意图

Figure 3.Schematic diagram of the experimental device of frequency offset effect on the characteristics of blue light

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图 4双波长泵浦铷蒸气实验装置图

Figure 4.Schematic diagram of experimental device of double-wavelength pumped rubidium vapor

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图 5泵浦光偏振与蓝光功率关系图

Figure 5.Relationship betweeen pump light polarization and blue laser power

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图 6在铷原子中引入795 nm 能级跃迁及部分实验装置示意图

Figure 6.Energy level structure of the rubidium atom and part of the experimental device when the 795 nm laser is introduced

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图 7涡旋光束在碱金属蒸气传递示意图

Figure 7.Transmission of the vortex beam in alkali vapor

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图 8国内首次实现双光子吸收碱金属蒸气输出的实验装置示意图

Figure 8.Schematic diagram of experimental device of two-photon absorption alkali vapor laser output realized in the domestic for the first time

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图 9铯原子能级跃迁及2.42 μm 对非线性过程调控示意图

Figure 9.Transition of cesium atom energy level and the control for nonlinear process by 2.42 μm laser

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表 1双光子吸收碱金属蒸气研究成果

Table 1.Experimental results of alkali metal vapor laser absorpted by two-photon

增益介质	泵浦光功率P_p/mW	蒸气池长度/cm	蒸气池温度/℃	蓝光功率P_blue
Cs^[33]	30(917 nm)	7	110	4 μW (455 nm)
Cs^[33]	30(852 nm)	7	110	4 μW (455 nm)
Rb^[27]	7(776 nm)	5	87	15 μW (420 nm)
Rb^[27]	7(780 nm)	5	87	15 μW (420 nm)
Rb^[34]	205(776 nm)	5	135	9.1 mW
Rb^[34]	390(780 nm)	5	135	9.1 mW
Rb^[28]	20(776 nm)	5	200	40 μW
Rb^[28]	20(780 nm)	5	200	40 μW
Rb^[35]	17(776 nm)	7.5	122	1.1 mW
Rb^[35]	25(780 nm)	7.5	122	1.1 mW
Cs^[36]	3.6(852 nm)	5	200	0.1 mW

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