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基于单谐振光参量振荡器产生可调谐中红外双频激光的研究

Tunable Mid-IR dual frequency laser based on a single-resonant optical parametric oscillator

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摘要

采用1064 nm双频连续激光泵浦基于周期极化铌酸锂晶体的单谐振光参量振荡器实现了双频中红外激光输出, 通过调节晶体的温度和极化周期, 实现了输出波长在3~3.8 μm范围可调谐.双频中红外激光的拍频与泵浦光拍频相同, 调谐范围为125~175 MHz.在泵浦光功率为6.9 W, 晶体极化周期30 μm, 晶体温度75℃时实现了1.25 W的双频中红外激光输出, 泵浦光-闲频光的最高转换效率为18.2%.通过调节双频激光的功率比, 可以改变输出中红外双频激光的调制深度.

Abstract

A Tunable Mid-IR dual frequency laser based on single-resonant optical parametric oscillator is presented. The mid-infrared wavelength tunability of 3~3.8 μm is achieved by adjusting the temperature and polarization period of MgO:PPLN crystal. When the pump power is 6.9 W and the temperature of the MgO:PPLN is 75℃, output power of 1.25 W is obtained. The highest optical-optical conversion efficiency of the idler light with respect to pump light is 18.2%. The beat note frequency is equal to the beat note frequency of the pump, which can be tuned from 125 to 175 MHz. The modulation index of the beat note of idle could be adjusted with different dual-frequency power radio of pump.

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中图分类号:O437

DOI:10.11972/j.issn.1001-9014.2019.02.012

基金项目:国家自然科学基金(61741502, 61835001, 61875011, 61205116)

收稿日期:2018-11-03

修改稿日期:2018-12-20

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作者单位    点击查看

李坤:北京理工大学 光电学院, 北京 100081
杨苏辉:北京理工大学 光电学院, 北京 100081精密光电测试仪器及技术北京市重点实验室, 北京 100081
王欣:北京理工大学 光电学院, 北京 100081
李卓:北京理工大学 光电学院, 北京 100081
张金英:北京理工大学 光电学院, 北京 100081

联系人作者:李坤(likun0377@126.com)

备注:李坤(1992-),男,河南南阳人,博士研究生,主要研究领域为固体激光器、激光雷达. E-mail: likun0377@126.com

【1】Vainio M, Peltola J, Persijn S, et al. Singly resonant cw OPO with simple wavelength tuning[J]. Optics Express, 2008, 16(15):11141-11146.

【2】Groot M L, Wilderen L J G W V, Larsen D S, et al. Initial steps of signal generation in photoactive yellow protein revealed with femtosecond mid-infrared spectroscopy.[J]. Biochemistry, 2003, 42(34):10054-10059.

【3】GUO Jing, HE Guang-Yuan, JIAO Zhong-Xing, et al. 2.1 μm optical parametric oscillator with high average power and narrow linewidth [J]. J. Infrared Millim.Waves (郭靖, 何广源, 焦中兴,等. 高功率窄线宽2.1 μm光学参量振荡器. 红外与毫米波学报) 2014, 33(6):625-628.

【4】DAI Hong, CHEN Chao-Jie. Implementation of helicopter airborne mid-ir laser directional interference [J]. Journal of ordnance equipment engineering , (代红, 陈超. 直升机机载中红外激光定向干扰实现途径. 兵器装备工程学报) 2011, 32(1):114-116.

【5】WANG Ling-Fang. Formaldehyde and methane spectroscopy measurements based on Mid-IR quantum cascade laser system[J]J. Infrared Millim.Waves (王玲芳. 基于中红外量子级联激光器系统的甲醛和甲烷光谱检测. 红外与毫米波学报) 2014, 33(6):591-597.

【6】Orphal J, Bergametti G, Beghin B, et al. Monitoring tropospheric pollution using infrared spectroscopy from geostationary orbit[J]. Comptes Rendus Physique, 2005, 6(8):888-896.

【7】Vercesi V, Onori D, Laghezza F, et al. Frequency-agile dual-frequency lidar for integrated coherent radar-lidar architectures[J]. Optics Letters, 2015, 40(7):1358-61.

【8】Eberhard W L, Schotland R M . Dual-frequency Doppler-lidar method of wind measurement[J]. Applied Optics, 1980, 19(17):2967.

【9】Liu J M, Diaz R, Chan S C. Lidar detection using a dual-frequency source[J]. Optics Letters, 2006, 31(24):3600-3602.

【10】Koch S E, Flamant C, Wilson J W, et al. An atmospheric soliton observed with doppler radar, differential absorption lidar and a molecular Doppler lidar[J]. Journal of Atmospheric & Oceanic Technology, 2008, 25(8):1267-1287.

【11】SUN You-Wen, LIU Wen-Qing, XIE Pin-Hua, et al. Measurement of industrial gas pollutant emissions using differential optical absorption spectroscopy[J], Acta Physica Sinica , (孙友文, 刘文清, 谢品华,等. 差分吸收光谱技术在工业污染源烟气排放监测中的应用. 物理学报) 2013, 62(1) 000094-103]

【12】Ramos J A, Osorio M, Belsterli G, et al. Differential optical absorption spectroscopy system for multi purpose applications[C]// Instrumentation and Measurement Technology Conference. IEEE, 2014:1193-1196.

【13】ZHU Shou-Shen, ZHANG Shu-Lian, LIU Wei-Xin, et al. Laser-micro-engraving metho d to mo dify frequency difference of two-frequency He-Ne lasers[J]Acta Physica Sinica,(朱守深, 张书练, 刘维新,等. He-Ne双频激光器频差的激光内雕赋值法. 物理学报)2014, 63(6):159-163.

【14】Mckay A, Dawes J, Dekker P, et al. A comparison of tunable, passively-stabilized two-frequency solid-state lasers for microwave generation[C]// International Topical Meeting on Microwave Photonics. IEEE, 2005:161-164.

【15】Danion G, Hamel C, Frein L, et al. Dual frequency laser with two continuously and widely tunable frequencies for optical referencing of GHz to THz beatnotes.[J]. Optics Express, 2014, 22(15):17673.

【16】Rolland A, Brunel M, Loas G, et al. Beat note stabilization of a 10–60 GHz dual polarization Nd:YAG microchip laser through optical down conversion[C]// Lasers and Electro-Optics Europe. IEEE, 2011:1-1.

【17】Le G J, Morvan L, Alouini M, et al. Dual-frequency single-axis laser using a lead lanthanum zirconate tantalate (PLZT) birefringent etalon for millimeter wave generation: beyond the standard limit of tunability.[J]. Optics Letters, 2007, 32(9):1090.

【18】Kim M S, Kim S W. Two-longitudinal-mode He-Ne laser for heterodyne interferometers to measure displacement[J]. Appl Opt, 2002, 41(28):5938-5942.

【19】HE Tao, YANG Su-Hui, ZHAO Chang-Ming, et al. High power tunable beat frequency signal by all fiber dual-frequency amplification[J]. High Power Laser and Particle Beams,(何滔, 杨苏辉, 赵长明,等. 高功率可调谐双频激光全光纤放大实验研究. 强激光与粒子束) 2014, 26(12):26121006.

【20】ZHENG Xiong-Hua, HE Guang-Yuan, JIAO Zhong-Xing, et al. Stable, high-average-power, continuous-wave singly resonant optical parametric oscillation based on angle-polished MgO:PPLN[J]. J. Infrared Millim.Waves,(郑雄桦, 何广源, 焦中兴,等. 基于角度切割MgO:PPLN晶体的高平均功率、稳定的连续波单振荡光学参量振荡器. 红外与毫米波学报) 2015, 34(6):684-687.

【21】Shukla M K, Maji P S, Das R. Yb-fiber laser pumped high-power, broadly tunable, single-frequency red source based on a singly resonant optical parametric oscillator[J]. Optics Letters, 2016, 41(13):3033.

【22】Yang J F , Liu S D , He J L, et al. Tunable simultaneous dual-wavelength laser at 1.9 and 1.7 μm based on KTiOAsO4 optical parametric oscillator[J]. Laser Physics Letters, 2011, 8(1):28-31.

【23】Chen T , Wu B , Liu W , et al. Efficient parametric conversion from 1.06 to 3.8 μm by an aperiodically poled cascaded lithium niobate.[J]. Optics Letters, 2011, 36(6):921-3.

【24】Zhao Sheng-Zhi. Nonlinear optics[M]. Jinan, Shandong university press,赵圣之. 非线性光学. 济南, 山东大学出版社), 2007:139.

【25】Bjorkholm J E. Some effects of spatially nonuniform pumping in pulsed optical parametric oscillators[J]. IEEE Journal of Quantum Electronics, 1971, 7(3):109-118.

引用该论文

LI Kun,YANG Su-Hui,WANG Xin,LI Zhuo,ZHANG Jin-Ying. Tunable Mid-IR dual frequency laser based on a single-resonant optical parametric oscillator[J]. Journal of Infrared and Millimeter Waves, 2019, 38(2): 195-202

李坤,杨苏辉,王欣,李卓,张金英. 基于单谐振光参量振荡器产生可调谐中红外双频激光的研究[J]. 红外与毫米波学报, 2019, 38(2): 195-202

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