Tunable deep ultraviolet femtosecond sum frequency laser based on Ba1-xB2-y-zO4SixAlyGaz crystal

Meng Xiang-Hao; Liu Hua-Gang; Huang Jian-Hong; Dai Shu-Tao; Deng Jing; Ruan Kai-Ming; Chen Jin-Ming; Lin Wen-Xiong

doi:10.7498/aps.64.164205

Abstract

Tunable coherent deep ultraviolet (DUV) light sources, especially ultrashort pulse DUV lasers have great applications in the fields of time-resolved, material processing, spectroscopy, laser spectroscopy and laser fusion. In the UV region, the best choice of generating the laser pulses in the femtosecond or picosecond regime is the frequency up-conversation technique based on second order nonlinearities. Over the past three decades, quite a lot of nonlinear crystals, such as LiB3O5, βup-BaB2O4, KBe2BO3F2 and Ba1-xB2-y- zO4SixAlyGaz have been developed and employed for generating the femtosecond pulses in the blue, ultraviolet, and even the deep-ultraviolet region. A tunable deep ultraviolet femtosecond laser is experimentally studied based on the new nonlinear crystal Ba1-xB2-y-zO4SixAlyGaz It is a kind of low-temperature phase barium metaborate single crystal belonging to a trigonal system, doped with one or more elements selected from Si, Al and Ga. As an optimized β-BaB2O4 crystal, Ba1-xB2-y-zO4SixAlyGaz completely overcomes the shortcomings of deliquescence compared with β-BaB2O4, and its nonlinear efficiency and optical damage threshold have also been greatly improved. Using two crystals as second harmonic generation is to compensate for the spatial walk-off effect and the light path walk-off due to refraction effect The optical axis of the second Ba1-xB2-y-zO4SixAlyGaz is twice the phase matching angle with respect to the first one. In a femtosecond regime, short pulse provides high efficient frequency conversation due to their high peak powers, but the group velocity mismatch is a cognitive factor to limit conversion efficiency. It is obvious that after the frequency doubling, the second harmonic pulse and fundamental pulse separate from each other. The second harmonic pulse lags behind the fundamental pulse as they propagate through the crystal and the second harmonic pulse is broadened into a longer pulse duration than the fundamental pulse The method to compensate for the group velocity mismatch is to adjust the path length between the fundamental and second harmonic pulse by means of time delay line. It consists of beam splitters and mirrors. Tunable deep ultraviolet pulse within a wavelength range from 192.5 to 210 nm is produced, with a maximum average power of 5.8 mW, under a 2.78 W fundamental power. The average power of second harmonic, third harmonic and fourth harmonic are 1.28 W, 194 mW and 5.8 mW at the fundamental wavelength of 800 nm, corresponding to conversion efficiencies of 46.14%, 15.16% and 3% from the previous stage, respectively. The duration of the third harmonic pulse is 640.4 fs at 266.7 nm as measured by the cross-correlation technique.

Keywords:

Authors and contacts

1.
Key Laboratory of Optoelectronic Materials Chemistry and Physics, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, Fuzhou 350002, China;
2.
University of Chinese Academy of Sciences, Beijing 100049, China
Funds: Project supported by the National Natural Science Foundation of China (Grant No. 11327804), the Instrument Developing Project of the Chinese Academy of Sciences (Grant No. yz201341), the Key Program of Industrial Science and Technology Plan of Fujian Province, China (Grant No. 2012H0050), the Young Scientists Fund of the National Natural Science Foundation of China (Grant No. 61205134), and the Chunmiao Project of Haixi Institute of Chinese Academy of Sciences (Grant No. CMZX-2014-002).

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Cited By

[1]	Chen C T, Lin Z S 2004 J. Synth. Crys. 33 455 (in Chinese) [陈创天, 林哲帅 2004 人工晶体学报 33 455]
[2]	Chen C T, Liu L J 2007 J. Chin. Ceram. Soc. 35 1 (in Chinese) [陈创天, 刘丽娟 2007 硅酸盐学报 35 1]
[3]	Gao Z Y, Zhu J F, Tian W L, Wang J L, Wang Q, Zhang Z G, Wei Z Y, Yu H H, Zhang H J, Wang J Y 2014 Chin. Phys. B 23 054207
[4]	He J L, Lu X Q, Jia Y L 2000 Acta Phys. Sin. 49 2106 (in Chinese) [何京良, 卢兴强, 贾玉磊 2000 49 2106]
[5]	Dubietis A, Tamošauskas G, Varanavičius A 2000 Opt. Lett. 25 1116
[6]	Liu H, Gong M L 2009 Acta Phys. Sin. 58 5443 (in Chinese) [刘欢, 巩马理 2009 58 5443]
[7]	Nebel A, Beigang R 1991 Opt. Lett. 16 1729
[8]	Liu H G, Hu M L, Liu B W, Song Y J, Chai L, Wang Q Y 2010 Acta Phys. Sin. 59 3979 (in Chinese) [刘华刚, 胡明列, 刘博文, 宋有建, 柴璐, 王清月 2010 59 3979]
[9]	Wang G, Wang X, Zhou Y, Li C, Zhu Y, Xu Z, Chen C 2008 Appl. Opt. 47 486
[10]	Chen C, Togashi T, Suganuma T, Sekikawa T, Watanabe S, Xu Z, Wang J 2002 Opt. Lett. 27 637
[11]	Chen C, Xu Z, Deng D, Zhang J, Wong G, Wu B 1996 Appl. Phys. Lett. 68 2930
[12]	Rotermund F, Petrov V 1998 Opt. Lett. 23 1040
[13]	Kanai T, Kanda T, Sekikawa T 2004 J. Opt. Soc. Am. B 21 370
[14]	Chen C Z 2011 US patent 2 322 697 [2011-07-14]
[15]	Wang R, Teng H, Wang N, Han H N, Wang Z H, Wei Z Y, Hong M C, Lin W X 2014 Opt. Lett. 39 2105
[16]	Gao L L, Tan H M, Chen Y X 2003 Laser Technology 3 245 (in Chinese) [高兰兰,檀慧明, 陈颖新 2003 激光技术 3 245]
[17]	Gehr R J, Kimmel R W, Smith A V 1998 Opt. Lett. 23 1298
[18]	Huang J, Chang Y, Shen T, Yang Y 2008 Opt. Commun. 281 5244
[19]	Dastmalchi B, Tassin P, Koschny T, Soukoulis C 2014 Phys. Rev. B 89 115123

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Vol. 64, Issue 16 - 2015-08-20

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