[1] Taubman MS, Scott DC, Myers TL, et al. Long wave infrared cavity enhanced sensors using quantum cascade lasers[C]. SPIE, 2005, 6010: 60100C.

[2] Sabbir L, Kevin A B, Laura X, et al. Noninvasive in vivo glucose sensing on human subjects using mid-infrared light[J]. Optics Express, 2014, 5(7): 2397-2401.

[3] Ren W, Jiang W Z, Frank K. Single-QCL-based absorption sensor for simultaneous trace-gas detection of CH4 and N2O[J]. Applied Physics B, 2014, 117: 245-251.

[4] HofstetterD, FaistJ. High performance quantum cascade lasers and their applications[M] //Solid-state mid-infrared laser sources.[S.l.]: Springer, 2003: 61- 98.

[5] Vodopyanov K. Pulsed mid-IR optical parametric oscillators[M/OL]//Solid-state mid-infrared laser sources, 2003: 141-178[2017-07-14]. https://link.springer.com/content/pdf/10.1007%2F3-540-36491-9.pdf.

[6] DeLoach L D, Page R H, Wilke G D, et al. . Transition metal-doped zinc chalcogenides: spectroscopy and laser demonstration of a new class of gain media[J]. IEEE Journal of Quantum Electronics, 1996, 32(6): 885-895.

[7] Adams J J, Bibeau C, Page R H, et al. 4.0-4.5 μm lasing of Fe∶ZnSe below 180 K, a new mid-infrared laser material[J]. Optics Letters, 1999, 24(23): 1720-1722.

[8] Velikanov S D, Danilov V P, Zakharov N G, et al. Fe 2+∶ZnSe laser pumped by a nonchain electric-discharge HF laser at room temperature [J]. Quantum Electronics, 2014, 44(2): 141-144.

[9] Evans J W, Berry P A, Schepler K L. A passively Q-switched CW-pumped Fe∶ZnSe laser[J]. IEEE Journal of Quantum Electronics, 2014, 50(3): 204-209.

[10] Myoung N, Fedorov V V, Mirov S B, et al. Temperature and concentration quenching of mid-IR photoluminescence in iron doped ZnSe and ZnS laser crystals[J]. Journal of Luminescence, 2012, 132(3): 600-606.

[11] Kernal J, Fedorov V V, Gallian A, et al. 3.9-4.8 μm gain-switched lasing of Fe∶ZnSe at room temperature[J]. Optics Express, 2005, 13(26): 10608-10615.

[12] JelinkovaH, Doroshenko ME, JelinekM, et al. Fe∶ZnSe laser oscillation under cryogenic and room temperature[C]. SPIE, 2013, 8599: 85990E.

[13] Zajac A, Skorczakowski M, Swiderski J, et al. Electrooptically Q-witched mid-infrared Er∶YAG laser for medical applications[J]. Optics Express, 2004, 12(21): 5262.

[14] Kozlovsky V I, Akimov V A, Frolov M P, et al. Room-temperature tunable mid-infrared lasers on transition-metal doped II—VI compound crystals grown from vapor phase[J]. Physica Status Solidi, 2010, 247(6): 1553-1556.

[15] Apollonov V V, Kazantsev S Y, Oreshkin V F, et al. Nonchain electric-discharge HF(DF) laser with a high radiation energy[J]. Quantum Electronics, 1998, 28(2): 116-118.

[16] 柯常军, 万重怡, 周锦文. 高峰值功率脉冲氟化氢激光器[J]. 激光技术, 2004, 28(5): 480-482.

    Ke C J, Wan C Y, Zhou J W. High peak power HF laser[J]. Laser Technology, 2004, 28(5): 480-482.

[17] 柯常军, 张阔海, 孙科, 等. 重复频率放电引发的脉冲HF(DF)激光器[J]. 红外与激光工程, 2007, 36(s1): 36-38.

    Ke C J, Zhang K H, Sun K, et al. A periodically pulsed HF/DF gas discharge laser[J]. Infrared and Laser Engineering, 2007, 36(s1): 36-38.

[18] Firsov K N, Gavrishchuk E M, Kazantsev S Y, et al. Increasing the radiation energy of ZnSe∶Fe 2+ laser at room temperature [J]. Laser Physics Letters, 2014, 11(9): 085001.

[19] Velikanov S D, Gavrishchuk E M, Zaretsky N A, et al. Repetitively pulsed Fe∶ZnSe laser with an average output power of 20 W at room temperature of the polycrystalline active element[J]. Quantum Electronics, 2017, 47(4): 303-307.

[20] 姚宝权, 夏士兴, 于快快, 等. Fe 2+∶ZnSe实现中红外波段激光输出 [J]. 中国激光, 2015, 42(1): 0119001.

    Yao B Q, Xia S X, Yu K K, et al. Fe 2+∶ZnSe achieving laser output [J]. Chinese Journal of Lasers, 2015, 42(1): 0119001.

[21] 柯常军, 王东蕾, 王向永, 等. 室温Fe 2+∶ZnSe激光器获得15 mJ中红外激光输出 [J]. 中国激光, 2015, 42(2): 0219004.

[22] Il'ichev N N, Shapkin P V, Kulevsky L A, et al. . Nonlinear transmittance of ZnSe∶Fe 2+ crystal at a wavelength of 2.92 μm [J]. Laser Physics, 2007, 17(2): 130-133.