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Diode-pumped composite ceramic Nd:YAG planar waveguide amplifier with 327 mJ output at 100 Hz repetition rate 被引量:5

Diode-pumped composite ceramic Nd:YAG planar waveguide amplifier with 327 mJ output at 100 Hz repetition rate
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摘要 We present a diode-pumped high-energy ceramic Nd:YAG planar waveguide that is demonstrated as a record in output energy for the ceramic planar waveguide fabricated by nonaqueous tape casting and solid-state reactive sintering. Under a repetition rate of 100 Hz and a pulse width of 250 μs, a maximum output pulse energy of 327 mJ is obtained with a beam quality factor of = 2.6 × 7.0. The corresponding peak power is 1308 W. The extraction efficiency of the system is about 56%. We present a diode-pumped high-energy ceramic Nd:YAG planar waveguide that is demonstrated as a record in output energy for the ceramic planar waveguide fabricated by nonaqueous tape casting and solid-state reactive sintering. Under a repetition rate of 100 Hz and a pulse width of 250 μs, a maximum output pulse energy of 327 mJ is obtained with a beam quality factor of = 2.6 × 7.0. The corresponding peak power is 1308 W. The extraction efficiency of the system is about 56%.
作者 刘娇 葛林 冯利文 姜豪 苏华 周唐建 王君涛 高清松 李江
机构地区 Institute of Applied Electronics Key Laboratory Science and Technology on High Energy Laser Gradute School Shanghai Institute of Ceramics Institute of Applied Physics and Computational Mathematics
出处 《Chinese Optics Letters》 SCIE EI CAS CSCD 2016年第5期61-65,共5页 中国光学快报(英文版)
基金 supported by the Key Laboratory of Science and Technology on High Energy Lasers(China Academy of Engineering Physics)
关键词 Ceramic materials Planar waveguides SINTERING WAVEGUIDES Ceramic materials Planar waveguides Sintering Waveguides
分类号 TN248 [电子电信—物理电子学] TN722 [电子电信—电路与系统]
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  • 1C. L. Bonner, T. Bhutta, D. P. Shepherd, and A. C. Tropper, IEEE J. Quantum Electron. 36, 236 (2000).
  • 2J. R. Lee, H. J. Baker, G. J. Friel, G. J. Hilton, and D. R. Hall, Opt. Lett. 27, 524 (2002).
  • 3L. Xiao, X. J. Cheng, and J. Q. XU, Opt. Commun. 281, 3781 (2008).
  • 4W. Bolanos, F. Starecki, A. Benayad, G. Brasse, V. Menard, J. L. Doualan, A. Braud, R. Moncorge, and P. Carny, Opt. Lett. 37, 4032 (2012).
  • 5F. Starecki, W. Bolanos, A. Braud, J. L. Doualan, G. Brasse, A. Benayad, V. Nazabal, B. Xu, R. Moncorge, and P. Carny, Opt. Lett. 38, 455 (2013).
  • 6I. J. Thomson, F. J. Monjardin, H. J. Baker, and D. R. Hall, IEEE J. Quantum Electron. 47, 1336 (2011).
  • 7I. J. Thomson, H. J. Baker, K. Wlodarczyk, N. Trela, and D. R. Hall, Proc. SPIE 7578, 14 (2010).
  • 8I. J. Thomson, K. L. Wlodarczyk, D. R. Hall, and H. J. Baker, in Lasers, Sources, and Related Photonic Devices (Optical Society of America, 2012), Paper No. AW4A.19.
  • 9C. Y. Ramirez-Corral, I. J. Thomson, C. G. Leburn, D. R. Hall, D. T. Reid, and H. J. Baker, in European Physical Journal Web of Conferences 41, 10013 (2013).
  • 10D. Filgas, T. Clatterbuck, M. Cashen, A. Daniele, S. Hughes, and D. Mordaunt, Proc. SPIE 8381, 83810W (2012).

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Chinese Optics Letters
2016年 第5期

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