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大口径多层介质膜光栅衍射效率测量及其在制作工艺中的应用

周小为 刘颖 徐向东 邱克强 刘正坤 洪义麟 付绍军

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大口径多层介质膜光栅衍射效率测量及其在制作工艺中的应用

周小为, 刘颖, 徐向东, 邱克强, 刘正坤, 洪义麟, 付绍军

Diffraction efficiency measurement of large aperture multilayer dielectric grating and its application in the fabrication process

Zhou Xiao-Wei, Liu Ying, Xu Xiang-Dong, Qiu Ke-Qiang, Liu Zhen-Kun, Hong Yi-Ling, Fu Shao-Jun
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  • 多层介质膜光栅是高功率激光系统的关键光学元件.为了满足国内强激光系统的迫切需求, 在大口径多层介质膜光栅的研制过程中,建立了单波长自准直条件下的衍射效率测量方法及其误差分析. 结果表明误差主要由探测器的噪声和测试人员的差异产生,对衍射效率测试精度的影响是±1%. 在此基础上,将光栅衍射效率及其分布测量技术应用于光栅制作工艺中, 作为大口径光栅无损检测的一种手段,如判断光栅掩模是否能进行离子束刻蚀、 离子束刻蚀的在线监测和是否需要再刻蚀,从而实现对大口径多层介质膜光栅离子束刻蚀过程的定量、 科学控制,提高了离子束刻蚀光栅制作工艺的成功率.利用上述技术,已成功研制出多块最大尺寸为 430 mm× 350 mm、线密度1740线/mm、平均衍射效率大于95%的多层介质膜光栅. 实验结果表明,该方法操作简单、测量快速准确,不必检测光栅微结构. 为大口径多层介质膜光栅研制的无损检测工程化奠定了基础.
    Large aperture multilayer dielectric grating (MDG) is one of the key elements of high-power laser systems. In order to meet the requirements for large aperture MLG in a high-power laser system, a diffraction efficiency measurement system is developed for characterizing the diffraction efficiency of large MDG at 1064 nm and Littrow mounting. Through analyzinge the main factors such as detector signal-to-noise ratio and operating staff, which influence the testing results during measurement, their difference is obtained to be less than ±1%, which proves that the method can be used to measure the diffraction efficiency of MDG. Based on a large number of experimental data, the optical characterization of MDG in a negative first-order Littrow configuration could provide some information about grating microstructure. So the diffraction efficiency measurements have a number of important applications in the fabrication process, as a nondestructive grating inspection tool, such as determining the suitable photoresist grating mask which meet the ion beam etching requirements, on line end-point detection during ion beam etching, and judging whether another etching is needed. Based on above techniques, a number of MDGs have been achieved, each of which has mean diffraction efficiency greater than 95% line density 1740 lines/mm, and aperture up to 430 mm×350 mm. The results show that this method can satisfy the requirements for simple operation, testing speediness and preciseness, in which any inspection is not necessary for the MDG microstructure paramters.
    • 基金项目: 国家高技术研究发展计划(批准号: 2007AA1416)和国家自然科学基金(批准号: 10875128)资助的课题.
    • Funds: Project supported by the National High Technology Research and Development Program of China (Grant No. 2007AA1416), and the National Natural Science Foundation of China (Grant No. 10875128).
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    Chen X R, Li C M, Wu J H, Hu Z Y 2010 SPIE 7849 78491Y

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  • [1]

    Xu X D, Hong Y L, Lu Y, Fu S J 2005 Physics 34 748 (in Chinese) [徐向东, 洪义麟, 刘颖, 付绍军 2005 物理 34 748]

    [2]

    Kong W J, Liu S J, Shen J, Shen Z C, Shao J D, Fan Z X 2006 Acta Phys. Sin. 55 1143 (in Chinese) [孔伟金, 刘世杰, 沈健, 沈自才, 邵建达, 范正修 2006 55 1143]

    [3]

    Kong W J, Yun M J, Sun X, Liu J H, Fan Z X, Shao J D 2008 Acta Phys. Sin. 57 4904 (in Chinese) [孔伟金, 云茂金, 孙欣, 刘均海, 范正修, 邵建达 2008 57 4904]

    [4]

    Kong W J, Wang S H, Wei S J, Yun M J, Zhang W F, Wang X J, Zhang M M 2011 Acta Phys. Sin. 60 114214 (in Chinese) [孔伟金, 王书浩, 魏世杰, 云茂金, 张文飞, 王心洁, 张蒙蒙 2011 60 114214]

    [5]

    Nguyen H T, Britten J A, Carlson T C, Nissen J D, Summers L J, Hoaglan C R, Aasen M D, Peterson J E, Jovanovic I 2005 SPIE 5991 59911M

    [6]

    Plymouth Grating Laboratory. http: // www. plymouthgrating. com / index. htm [2011-12-12]

    [7]

    Xu X D, Hong Y L, Fu S J, Wang Z S 2004 Physics 33 340 (in Chinese) [徐向东, 洪义麟, 付绍军, 王占山 2004 物理 33 340]

    [8]

    Xu X D, Liu Z K, Qiu K Q, Liu Y, Hong Y L, Fu S J 2011 Acta Opt.Sin. 31 1005008 (in Chinese) [徐向东, 刘正坤, 邱克强, 刘颖, 洪义麟, 付绍军 2011 光学学报 31 1005008]

    [9]

    Britten J A, Molander W, Komashko A M, Bart C P J 2004 SPIE 5273 1

    [10]

    Wei S M, Li L F 2008 Appl. Opt. 47 2524

    [11]

    Lu P P, Sun K X, Byer R L, Britten J A, Nguyen H T, Nissen J D, Larson C C, Aasen M D, Carlson T C, Hoaglan C R 2009 Opt. Lett. 34 1708

    [12]

    Kou J T, Bayanheshig, Tang Y G, Qi X D, Yu H Z 2011 Acta Opt. Sin. 31 0705002-1 (in Chinese) [寇婕婷, 巴音贺希格, 唐玉国, 齐向东, 于宏柱 2011 光学学报 31 0705002]

    [13]

    Chen X R, Li C M, Wu J H, Hu Z Y 2010 SPIE 7849 78491Y

    [14]

    Hehl K, Bischoff J, Mohaupt U, Palme M, Schnable B, Wenke L, Bödefeld R, Theobald W, Welsch E, Sauerbrey R, Heyer H 1999 Appl. Opt. 38 6257

    [15]

    Lin H, Li L F, Zeng L J 2005 Chinese Opt. Lett. 3 63

    [16]

    Liu Y, Xu X D, Hong Y L, Xu D Q, Fu S J ZL 2007 1 0020220.0 (in Chinese) [2010-02-24] [刘颖, 徐向东, 洪义麟, 徐德权, 付绍军 ZL 2007 1 0020220.0 [2010-02-24]]

    [17]

    Chen S B, Sheng B, Qiu K Q, Liu Z K, Xu X D, Liu Y, Hong Y L, Fu S J 2011 High Power Laser & Partical Beams 23 2106 (in Chinese) [陈上碧, 盛斌, 邱克强, 刘正坤, 徐向东, 刘颖, 洪义麟, 付绍军 2011 强激光与粒子束 23 2106]

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出版历程
  • 收稿日期:  2011-12-21
  • 修回日期:  2012-02-21
  • 刊出日期:  2012-09-05

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