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赫兹型微裂纹光场调制增强作用的系统研究

蔡月飞 吕志伟 李森森 王雨雷 朱成禹 林殿阳 何伟明

赫兹型微裂纹光场调制增强作用的系统研究

蔡月飞, 吕志伟, 李森森, 王雨雷, 朱成禹, 林殿阳, 何伟明
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  • 通过改变裂纹的倾角、宽度和深度参数,模拟了赫兹型裂纹在不同参数下对光场调制能力的不同. 模拟发现,倾斜角度为20.9°到45°之间的裂纹危害最大,倾角大于45°小于48.2°的裂纹危害也十分大,而倾斜角度为45°时的裂纹危害最小. 对于30°倾角的赫兹型裂纹,一定范围内,赫兹型裂纹深度的增加会导致其光场调制增强能力呈二次方关系增加,但宽度的增加不会使其光场调制增强作用增加. 裂纹深度和宽度的增加可以用来近似裂纹的演化过程,所以裂纹的扩展导致了其光场调制能力的增加,进而导致损伤增长速率的加快,这和e指数损伤增长规律相符.
    [1]

    Demos S G, Kozlowski M R, Staggs M C 2001 International Society for Optics and Photonics Boulder, October 16, 2000 p277

    [2]

    Bloembergen N 1973 Applied Optics 12 661

    [3]

    Genin F Y, Salleo A, Pistor T V 2001 JOSA A 18 2607

    [4]

    Wang Y, Xu Q, Chai L Q, Chen N, Zhu X Q 2005 High Power Laser and Part. Beams 17 67 (in Chinese) [王毅, 许乔, 柴立群 2005 强激光与粒子束 17 67]

    [5]

    Chai L Q, Ge D B, Xu Q 2005 Optical Technique 31 24 (in Chinese) [柴立群, 葛德彪, 许乔 2005 光学技术 31 24]

    [6]

    Tian D B, Yuan X D, Zu X T 2008 High Power Laser and Part. Beams 319 (in Chinese) [田东斌, 袁晓东, 祖小涛 2008 强激光与粒子束 20 319]

    [7]

    Hua J R, Li L, Xiang X 2011 Acta Phys. Sin. 60 044206 (in Chinese) [花金荣, 李莉, 向霞 2011 物理学报 60 044206]

    [8]

    Li L, Xia X, Xiao-Tao Z 2011Chin. Phys. B 20 074209

    [9]

    Zhang L, Chen W, Hu L 2013 Applied Optics 52 980

    [10]

    Rubenchik A M, Feit M D 2002 International Society for Optics and Photonics Boulder 2002 p79

    [11]

    Norton M A, Hrubesh L W, Wu Z 2001 Proc. SPIE. 2001 p4347

    [12]

    Norton M A, Carr A V, Carr C W 2008 International Society for Optics and Photonics Boulder Damage Symposium XL Annual Symposium on Optical Materials for High Power Lasers Boulder, September 22, 2008 p71321H

    [13]

    Lawn B, Wilshaw R 1975Journal of Materials Science 10 1049

    [14]

    Hamza A V, Siekhaus W J, Rubenchik A M Boulder Damage International Society for Optics and Photonics Boulder, October 01, 2001 p96

    [15]

    Hrubesh L W, Norton M A 2001 LLNL REPORT 2001 UCRL-JC-144295 p1

    [16]

    Yin W, Xu S Z, Zu X T 2009 Atomic Energy Science and Technology 43 860 (in Chinese) [尹伟, 徐世珍, 祖小涛 2009 原子能科学技术 43 860]

    [17]

    Bass I L, Guss G M, Hackel R P 2005 Boulder Damage Symposium XXXVII: Annual Symposium on Optical Materials for High Power Lasers. International Society for Optics and Photonics Boulder, September 19, 2005 p59910C

    [18]

    Gallais L, Cormont P, Rullier J L 2009 Opt. Express 17 p23488

  • [1]

    Demos S G, Kozlowski M R, Staggs M C 2001 International Society for Optics and Photonics Boulder, October 16, 2000 p277

    [2]

    Bloembergen N 1973 Applied Optics 12 661

    [3]

    Genin F Y, Salleo A, Pistor T V 2001 JOSA A 18 2607

    [4]

    Wang Y, Xu Q, Chai L Q, Chen N, Zhu X Q 2005 High Power Laser and Part. Beams 17 67 (in Chinese) [王毅, 许乔, 柴立群 2005 强激光与粒子束 17 67]

    [5]

    Chai L Q, Ge D B, Xu Q 2005 Optical Technique 31 24 (in Chinese) [柴立群, 葛德彪, 许乔 2005 光学技术 31 24]

    [6]

    Tian D B, Yuan X D, Zu X T 2008 High Power Laser and Part. Beams 319 (in Chinese) [田东斌, 袁晓东, 祖小涛 2008 强激光与粒子束 20 319]

    [7]

    Hua J R, Li L, Xiang X 2011 Acta Phys. Sin. 60 044206 (in Chinese) [花金荣, 李莉, 向霞 2011 物理学报 60 044206]

    [8]

    Li L, Xia X, Xiao-Tao Z 2011Chin. Phys. B 20 074209

    [9]

    Zhang L, Chen W, Hu L 2013 Applied Optics 52 980

    [10]

    Rubenchik A M, Feit M D 2002 International Society for Optics and Photonics Boulder 2002 p79

    [11]

    Norton M A, Hrubesh L W, Wu Z 2001 Proc. SPIE. 2001 p4347

    [12]

    Norton M A, Carr A V, Carr C W 2008 International Society for Optics and Photonics Boulder Damage Symposium XL Annual Symposium on Optical Materials for High Power Lasers Boulder, September 22, 2008 p71321H

    [13]

    Lawn B, Wilshaw R 1975Journal of Materials Science 10 1049

    [14]

    Hamza A V, Siekhaus W J, Rubenchik A M Boulder Damage International Society for Optics and Photonics Boulder, October 01, 2001 p96

    [15]

    Hrubesh L W, Norton M A 2001 LLNL REPORT 2001 UCRL-JC-144295 p1

    [16]

    Yin W, Xu S Z, Zu X T 2009 Atomic Energy Science and Technology 43 860 (in Chinese) [尹伟, 徐世珍, 祖小涛 2009 原子能科学技术 43 860]

    [17]

    Bass I L, Guss G M, Hackel R P 2005 Boulder Damage Symposium XXXVII: Annual Symposium on Optical Materials for High Power Lasers. International Society for Optics and Photonics Boulder, September 19, 2005 p59910C

    [18]

    Gallais L, Cormont P, Rullier J L 2009 Opt. Express 17 p23488

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出版历程
  • 收稿日期:  2013-07-04
  • 修回日期:  2013-08-19
  • 刊出日期:  2013-12-05

赫兹型微裂纹光场调制增强作用的系统研究

  • 1. 哈尔滨工业大学光电子研究所, 可调谐激光国家重点实验室, 哈尔滨 150001

摘要: 通过改变裂纹的倾角、宽度和深度参数,模拟了赫兹型裂纹在不同参数下对光场调制能力的不同. 模拟发现,倾斜角度为20.9°到45°之间的裂纹危害最大,倾角大于45°小于48.2°的裂纹危害也十分大,而倾斜角度为45°时的裂纹危害最小. 对于30°倾角的赫兹型裂纹,一定范围内,赫兹型裂纹深度的增加会导致其光场调制增强能力呈二次方关系增加,但宽度的增加不会使其光场调制增强作用增加. 裂纹深度和宽度的增加可以用来近似裂纹的演化过程,所以裂纹的扩展导致了其光场调制能力的增加,进而导致损伤增长速率的加快,这和e指数损伤增长规律相符.

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