Joule-Level High Energy Mid-Infrared Solid Fe<bold>∶</bold>ZnSe Laser

Fei Xu; Qikun Pan; Yueru Zhang; Yi Chen; Deyang Yu; Kuo Zhang; Ranran Zhang; Junjie Sun; Fei Chen

doi:10.3788/CJL221449

Chinese Journal of Lasers, Volume. 50, Issue 22, 2201001(2023)

Joule-Level High Energy Mid-Infrared Solid Fe∶ZnSe Laser

Fei Xu^1,2, Qikun Pan^1、*, Yueru Zhang^1,2, Yi Chen¹, Deyang Yu¹, Kuo Zhang¹, Ranran Zhang¹, Junjie Sun¹, and Fei Chen¹

¹State Key Laboratory of Laser Interaction with Matter, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, Jilin, China

²University of Chinese Academy of Sciences, Beijing 100049, China

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References(16)

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[2] Sun X, Han L, Wang K Q. Progress in directly pumping of mid-infrared solid-state lasers[J]. Laser & Optoelectronics Progress, 54, 050007(2017).

[3] 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, 24, 1720-1722(1999).

[4] Mirov S B, Fedorov V, Martyshkin D et al. High average power Fe∶ZnSe and Cr∶ZnSe mid-IR solid state lasers[C], AW4A.1(2015).

[5] Velikanov S D, Zaretskiy N A, Zotov E A et al. Investigation of Fe∶ZnSe laser in pulsed and repetitively pulsed regimes[J]. Quantum Electronics, 45, 1-7(2015).

[6] Velikanov S D, Zaretsky N A, Zotov E A et al. Room-temperature 1.2-J Fe2+∶ZnSe laser[J]. Quantum Electronics, 46, 11-12(2016).

[7] Frolov M P, Korostelin Y V, Kozlovsky V I et al. Efficient 10-J pulsed Fe∶ZnSe laser at 4100 nm[C], R1-10(2016).

[8] Fedorov V, Martyshkin D, Karki K et al. Q-switched and gain-switched Fe∶ZnSe lasers tunable over 3.60-5.15 µm[J]. Optics Express, 27, 13934-13941(2019).

[9] Pushkin A V, Migal E A, Tokita S et al. Femtosecond graphene mode-locked Fe∶ZnSe laser at 4.4 µm[J]. Optics Letters, 45, 738-741(2020).

[10] Shen Y L, Wan Y C, Wang Y S et al. Watt-level high efficiency mid-infrared 3.8 μm continuous-wave all solid-state Fe∶ZnSe laser[J]. Chinese Journal of Lasers, 50, 1401005(2023).

[11] Pan Q K, Xie J J, Chen F et al. Mid-infrared high energy Fe2+∶ZnSe laser at room temperature[J]. Chinese Journal of Lasers, 45, 1101001(2018).

[12] Li Y Y, Dai T Y, Duan X M et al. Fe∶ZnSe laser pumped by a 2.93-μm Cr, Er∶YAG laser[J]. Chinese Physics B, 28, 064203(2019).

[13] Pan Q K, Xie J J, Chen F et al. Transversal parasitic oscillation suppression in high gain pulsed Fe2+∶ZnSe laser at room temperature[J]. Optics & Laser Technology, 127, 106151(2020).

[14] Xu F, Pan Q K, Chen F et al. Theoretical characteristics of mid-infrared gain switched pulsed iron-doped ZnSe laser[J]. Optics & Laser Technology, 152, 108173(2022).

[15] Evans J W, Harris T R, Reddy B R et al. Optical spectroscopy and modeling of Fe2+ ions in zinc selenide[J]. Journal of Luminescence, 188, 541-550(2017).

[16] Firsov K N, Gavrishchuk E M, Kazantsev S Y et al. Increasing the radiation energy of ZnSe∶Fe2+ laser at room temperature[J]. Laser Physics Letters, 11, 085001(2014).

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Fei Xu, Qikun Pan, Yueru Zhang, Yi Chen, Deyang Yu, Kuo Zhang, Ranran Zhang, Junjie Sun, Fei Chen. Joule-Level High Energy Mid-Infrared Solid Fe∶ZnSe Laser[J]. Chinese Journal of Lasers, 2023, 50(22): 2201001

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Paper Information

Category: laser devices and laser physics

Received: Nov. 24, 2022

Accepted: Dec. 21, 2022

Published Online: Nov. 1, 2023

The Author Email: Pan Qikun (panqikun2005@163.com)

DOI:10.3788/CJL221449

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology