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1 110 nm Nd:GGG 激光器与555 nm 倍频激光器

周景涛 黄敬霞 李莉

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文章导航 > 红外与激光工程  > 2015 >  44(3): 867-871
周景涛, 黄敬霞, 李莉. 1 110 nm Nd:GGG 激光器与555 nm 倍频激光器[J]. 红外与激光工程, 2015, 44(3): 867-871.
引用本文: 周景涛, 黄敬霞, 李莉. 1 110 nm Nd:GGG 激光器与555 nm 倍频激光器[J]. 红外与激光工程, 2015, 44(3): 867-871.
shu
Zhou Jingtao, Huang Jingxia, Li Li. Nd:GGG laser at 1 110 nm and frequency-doubled laser at 555 nm[J]. Infrared and Laser Engineering, 2015, 44(3): 867-871.
Citation: Zhou Jingtao, Huang Jingxia, Li Li. Nd:GGG laser at 1 110 nm and frequency-doubled laser at 555 nm[J]. Infrared and Laser Engineering, 2015, 44(3): 867-871.
shu

1 110 nm Nd:GGG 激光器与555 nm 倍频激光器

  • 1.

    军械工程学院车辆与电气工程系,河北石家庄050003;

  • 2.

    军械工程学院光学与电子工程系,河北石家庄050003

基金项目: 

院国家自然科学基金(11004122)

详细信息
    作者简介:

    周景涛(1981-),男,硕士,主要从事激光物理与技术方面的研究.Email:luori810115@163.com

  • 中图分类号: TN248.1

Nd:GGG laser at 1 110 nm and frequency-doubled laser at 555 nm

  • 1.

    Department of Vehicle and Electric Engineering,Ordnance Engineering College,Shijiazhuang 050003,China;

  • 2.

    Department of Optics and Electronic Engineering,Ordnance Engineering College,Shijiazhuang 050003,China

  • 摘要: 采用紧凑的直腔设计和精确的膜系设计, 实现了LD 侧面泵浦1 110 nm Nd:GGG 和腔内倍频的555 nm 激光.当泵浦功率为168 W时, 得到了25.5 W的1110 nm 连续激光输出.在10 kHz 的声光调Q 情况下, 应用II 类非临界相位匹配LiB3O5(LBO)倍频晶体, 得到了最大输出功率为3.1 W的555 nm 倍频光输出, 光-光转换效率为1.8 %, 相应的脉冲宽度为176 ns, 在水平和竖直方向上的M2因子分别为19.6 和21.3.
    Abstract: A high-power diode-side-pumped 1 110 nm Nd:GGG laser and a laser at 555 nm based on intracavity frequency doubling of 1 110 nm laser were demonstrated for the first time. A simple straight cavity scheme was employed to achieve a compact configuration and all the coatings were designed specially. A 25.5 W 1 110 nm laser continuous wave output was achieved under the incident pump power of 168 W. A LiB3O5 (LBO)crystal was used for second harmonic generation of the laser. As a result, at the pump power of 168 W, the maximum power of the frequency-doubled output at 555 nm was found to be 3.1 W with a pulse repetition rate of 10 kHz, corresponding to an optical-to-optical conversion efficiency of about 1.8%. And the pulse width of 555 nm wave was 176 ns. The M2 factors are measured to be 19.6 and 21.3 in the horizontal and vertical directions, respectively.
  • [1] Yu Haohai, Wu Kui, Zhan Huaijin, et al. Nd: YGG crystal laser at 1110 nm: a potential source for detecting carbon monoxide poisoning[J]. Optics Letters, 2011, 36(7): 1281-1283. (in Chinese)
    [2]
    [3] Li C Y, Bo Y, Yang F, et al. A kilowatt level diode-side-pumped QCW Nd: YAG ceramic laser[J]. Optics Communications, 2010, 283(24): 5145-5148. (in Chinese)
    [4]
    [5]
    [6] Lv Yanfei, Zhang Xihe, Tan Huiming. 555 nm all solid-state continaous-wave yellow-green laser[J]. Optics Precision Engineering, 2007, 15(5): 0674-0678. (in Chinese)
    [7] Wu Y, Zhang X H, Sun G C. All-solid-state doubly resonant sum-frequency mixing laser at 555 nm[J]. Laser Physics, 2011, 21(6): 1074-1077.
    [8]
    [9] Mildren R P, Convery M, Pask H M, et al. Efficient, all-solid-state, raman laser in the yellow, orange and red[J]. Macquarie University Research, 2004, 12(5): 785-790.
    [10]
    [11] Wang Zhichao, Peng Qinjun, Bo Yong, et al. 60 W yellow laser at 561 nm by intracavity frequency doubling of a diode-pumped Q-switched Nd: YAG laser[J]. Optics Communications, 2012, 285(3): 328-330. (in Chinese)
    [12]
    [13]
    [14] Li Y L, Li J H, Liu X H, et al. 555 nm laser sources based on intracavity frequency doubling of Nd: YGG laser[J]. Solid State and Liquid Lasers, 2012, 22(3): 527-530.
    [15] Dong Yue, Zu Jifeng, Hou Liqun, et al. Approximate formulas of temperature and stress distributions and thermal induced effects in a heat capacity slab laser[J]. Chinese Optics Letters, 2006, 4(6): 326-328. (in Chinese)
    [16]
    [17] Zuo C H, Zhang B T, He J L, et al. The acousto-optical Q-switched Nd: GGG laser[J]. Laser Physics Letters, 2008, 5(10): 719-721.
    [18]
    [19]
    [20] Zuo Chunhua, He Jingliang, Huang Haitao, et al. Efficient passively Q-switched operation of a diode-pumped Nd: GGG laser with a Cr4+: YAG saturable absorber[J]. Optics Laser Technology, 2009, 41(1): 17-20. (in Chinese)
    [21] Li Z Y, Huang H T, He J L, et al. High peak power eye-safe intracavity optical parametric oscillator pumped by a diode-pumped passively Q-switched ND: GGG laser[J]. Laser Physics , 2010, 20(6): 1302-1306.
    [22]
    [23] Zuo C H, Zhang B T, He J L, et al. CW and passively Q-switching characteristics of a diode-end-pumped Nd: GGG laser at 1 331 nm[J]. Optical Materials, 2009, 31(6): 976-979.
    [24]
    [25]
    [26] Zuo C H, Zhang B T, Liu Y B, et al. Diode-pumped passively Q-switched and mode-locked Nd: GGG laser at 1.3m with V3+: YAG saturable absorber[J]. Laser Physics, 2010, 20(8): 1717-1720.
    [27] He Kunna, Gao Chunqing, Wei Zhiyi, et al. Diode-pumped quasi-three-level passively Q-switched Nd: GGG laser with a codoped Nd, Cr: YAG saturable absorber [J]. Chinese Phys Lett, 2009, 26(9): 137-139. (in Chinese)
    [28]
    [29] Huang Haitao, He Jingliang, Zhang Baitao, et al. V3+: YAG as the saturable absorber for a diode-pumped quasi-three-level dual-wavelength Nd: GGG laser[J]. Optics Express, 2010, 18(4): 3352-3357. (in Chinese)
    [30]
    [31] Zhang X L, Zhang X Y, Wang Q P, et al. LD side-pumped Nd: GGG CW laser operating at 1110 and 1105 nm dual wavelengths and 1 110 nm single wavelength[J]. Laser Physics, 2011, 21(6): 1047-1050.
    [32]
    [33] Zhang S S, Wang Q P, Zhang X Y, et al. High power and highly efficient Nd: YAG laser emitting at 1 123 nm[J], Laser Physics, 2009, 19(12): 2159-2162.
    [34]
    [35] Li C Y, Bo Y, Xu Y T, et al. 219.3 W CW diode-side-pumped 1 123 nm Nd: YAG laser[J]. Optics Communications, 2010, 283: 2885-2887. (in Chinese)
    [36]
    [37] Wang Zhichao, Peng Qinjun, Bo Yong, et al. Yellow-green 52.3 W laser at 556nm based on frequency doubling of a diode side-pumped Q-switched Nd: YAG laser[J]. Applied Optics, 2010, 49(18): 3465-3469.
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  • 收稿日期:  2014-07-05
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1 110 nm Nd:GGG 激光器与555 nm 倍频激光器

  • 1. 军械工程学院车辆与电气工程系,河北石家庄050003;
  • 2. 军械工程学院光学与电子工程系,河北石家庄050003
    • 作者简介:

    周景涛(1981-),男,硕士,主要从事激光物理与技术方面的研究.Email:luori810115@163.com

  • 收稿日期: 2014-07-05
  • 修回日期: 2014-08-15
  • 刊出日期: 2015-03-25
基金项目:

院国家自然科学基金(11004122)

  • 中图分类号: TN248.1

摘要: 采用紧凑的直腔设计和精确的膜系设计, 实现了LD 侧面泵浦1 110 nm Nd:GGG 和腔内倍频的555 nm 激光.当泵浦功率为168 W时, 得到了25.5 W的1110 nm 连续激光输出.在10 kHz 的声光调Q 情况下, 应用II 类非临界相位匹配LiB3O5(LBO)倍频晶体, 得到了最大输出功率为3.1 W的555 nm 倍频光输出, 光-光转换效率为1.8 %, 相应的脉冲宽度为176 ns, 在水平和竖直方向上的M2因子分别为19.6 和21.3.

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