[1] Low W, Weger M. Paramagnetic resonance and optical spectra of divalent iron in cubic fields. II. Experimental results[J]. Phys Rev, 1960, 118(5):1130-1136.
[2] Pappalardo R, Dietz R E. Absorption spectra of transition ions in CdS crystals[J]. Phys Rev, 1961, 123(4):1188-1203.
[3] Baranowski J M, Allen J W, Pearson G L. Crystal-field spectra of 3dn impurities in II-VI and III-V compound semiconductors[J]. Phys Rev, 1967, 160(3):627-632.
[4] Fazzio A, Caldas M J, Zunger A. Many-electron multiplet effects in the spectra of 3d impurities in heteropolar semiconductors[J]. Phys Rev, 1984, B30(6):3430-3455.
[5] 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 J Quantum Electron, 1996, 32(6):885-895.
[6] Adams J J, Bibeau C, Page R H, et al. 4.0-4.5m lasing of Fe:ZnSe below 180 K, a new mid-infrared laser material[J]. Opt Lett, 1999, 24(23):1720-1722.
[7] Jelinkova H, Doroshenko M E, Jelinek M, et al. Fe:ZnSe laser oscillation under cryogenic and room temperature[C]//SPIE, 2013, 8599:85990E1-7.
[8] 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.
[9] 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]. Status Solidi B, 2010, 247(6):1553-1556.
[10] Doroshenko M E, Jelinkova H, Basiev T T, et al. Fe:ZnSe laser comparison of active materials grown by two different methods[C]//SPIE, 2011, 7912:79122D1-6.
[11] Demirbas U, Sennaroglu A, Somer M. Synthesis and characterization of diffusion-doped Cr2+:ZnSe and Fe2+:ZnSe[J]. Optical Materials, 2006, 28:231-240.
[12] Kernal J, Fedorov V V, Gallian A, et al. 3.9-4.8m gain-switched lasing of Fe:ZnSe at room temperature[J]. Opt Express, 2005, 13(26):10608-10615.
[13] Mirov S B, Fedorov V V, Martyshkin D V, et al. Progress in Mid-IR Cr2+ and Fe2+ doped II-VI materials and lasers[J]. Op Mat Exp, 2011, 1(5):898-910.
[14] Akimov V A, Voronov A A, Kozlovskii V I, et al. Efficient IR Fe:ZnSe laser continusouly tunable in the spectral range from 3.77 to 4.40 microns[J]. Quantum Electron, 2004, 34(10):912-914.
[15] Voronov A A, Kozlovskii V I, Korostelin Y V, et al. Laser parameters of a Fe:ZnSe laser crystal in the 85-255 K temperature range[J]. Quantum Electron, 2005, 35(9):809-812.
[16] Fedorov V V, Martyshkin D V, Mirov M, et al. High energy 4.1-4.6m Fe:ZnSe laser[C]//CLEO, 2012, CM3D:CM3D.3.
[17] Ilichev N N, Danilov V P, Kalinushkin V P, et al.Superluminescent room-temperature Fe2+:ZnSe IR radiation source[J]. Quantum Electron, 2008, 38(2):95-96.
[18] Myoung N, Martyshkin D V, Fedorov V V, et al. Energy scaling of 4.3m room temperature Fe:ZnSe laser[J]. Opt Lett, 2011, 36(1):94-96.
[19] Frolov M P, Korostelin Y V, Kozlovsky V I, et al. Study of a 2-J pulsed Fe:ZnSe 4-m laser[J]. Laser Phys Lett, 2013, 10:25001-125007.
[20] Velikanov S D, Danilov V P, Zakharov N G, et al. Fe2+:ZnSe laser pumped by a nonchain electric-discharge HF laser at room temperature[J]. Quantum Electron, 2014, 44(2):141-144.
[21] Firsov K N, Gavrishchuk E M, Kazantsev S Yu, et al. Increasing the radiation energy of ZnSe:Fe2+ laser at room temperature[J]. Laser Phys Lett, 2014, 11:085001.
[22] Yao Baoquan, Xia Shixing, Yu Kuaikuai, et al. Fe2+:ZnSe achieving laser output[J]. Chinese J Laser, 2015, 42(1):0119001. (in Chinese)姚宝权, 夏士兴, 于快快, 等. Fe2+:ZnSe实现中红外波段激光输出[J]. 中国激光, 2015, 42(1):0119001.
[23] Ke Changjun, Wang Ran, Wang Xiangyong, et al. 15 mJ Fe2+:ZnSe laser operating at room temperature[J]. Chinese J Laser, 2015, 42(2):0219004. (in Chinese)柯常军, 王然, 王向永, 等. 室温Fe2+:ZnSe激光器获得15 mJ激光输出[J]. 中国激光, 2015, 42(2):0219004.
[24] Voronov A A, Kozlovskii V I, Korostelin Y V, et al. A continuous-wave Fe2+:ZnSe Laser[J]. Quantum Electron, 2008, 38(12):1113-1116.
[25] Evans J W, Berry P A, Schepler L L. 840 mW continuous wave Fe:ZnSe laser operating at 4140 nm[J]. Opt Lett, 2012, 37(23):5021-5023.
[26] Evans J W, Berry P A, Schepler L L. A passively Q-switched. CW-pumped Fe:ZnSe Laser[J]. IEEE J Quantum Electron, 2014, 50(3):204-209.
[27] Fedorov V, Martyshkin D, Mirov M, et al. Fe-doped II-VI mid-infrared laser materials for the 3 to 8m region[C]//CLEO, 2013, JM4K:JM4K.2.
[28] Akimov V A, Voronov A A, Kozlovskii V I, et al. Efficient lasing in a Fe2+:ZnSe crystal at room temperature[J]. Quantum Electron, 2006, 36(4):299-301.
[29] Doroshenko M E, Jelinkova H, Koranda P. Tunable mid-infrared laser properties of Cr2+:ZnMgSe and Fe2+:ZnSe crystals[J]. Laser Phys Lett, 2010, 7(1):38-45.
[30] Ke Changjun, Wan Chongyi, Zhou Jinwen, et al. High peak power HF laser[J]. Laser Technology, 2004, 28(5):480-484. (in Chinese)柯常军, 万重怡, 周锦文, 等. 高峰值功率脉冲氟化氢激光器[J]. 激光技术, 2004, 28(5):480-484.
[31] Apollonov V V, Belevtsev A A, Firsov K N, et al. Advanced studies on powerful wide-aperture non-chain HF(DF) lasers with a self-sustained volume discharge to initiate chemical reaction[C]//SPIE, 2003, 5120:529-541.
[32] Ke Changjun, Zhang Kuohai, Sun Ke, et al. Study on repetitive discharge-pulsed HF/DF laser[J]. Infrared and Laser Engineering, 2009, 36(S):36-38. (in Chinese)柯常军, 张阔海, 孙科, 等. 放电引发的重复频率脉冲HF/DF激光技术研究[J]. 红外与激光工程, 2009, 36(S):36-38.
[33] Butsykin I L, Velikanov S D, Evdokimov P A, et al. Repetitively pulsed DF laser with a pulse repetition rate up to 1200 Hz and an average output power of-25 W[J]. Quantum Electron, 2001, 31(11):957-961.
[34] Luo Wei, Yuan Shengfu, Lu Qisheng. Research development of small scale discharge driven continuous wave HF/DF chemical laser[J]. Laser Infrared, 2011, 41(4):371-375. (in Chinese)罗威, 袁圣付, 陆启生. 小型电激励连续波HF/DF化学激光器研究进展[J]. 激光与红外, 2011, 41(4):371-375.