电铸金属光栅中金属沉积过程的在线监测

朱春霖; 胡昊; 焦庆斌; 谭鑫; 巴音贺希格

doi:10.3788/CO.20191203.0606

电铸金属光栅中金属沉积过程的在线监测

doi: 10.3788/CO.20191203.0606

朱春霖^{1, 2,},
胡昊^{1, 2,},
焦庆斌^1,,
谭鑫^1,,
巴音贺希格^1, ,

1.
中国科学院长春光学精密机械与物理研究所, 吉林长春 130033
2.
中国科学院大学, 北京 100049

基金项目:

国家自然科学基金项目 61227901

国家自然科学基金项目 61605197

详细信息

作者简介:
朱春霖(1991—)，男，吉林梅河口人，博士研究生，2014年于北京理工大学获得学士学位，主要从事光栅湿法刻蚀等方面的研究。E-mail:zhuchunlin_optik@163.com

胡昊(1990—)，男，吉林松原人，博士研究生，2013年于电子科技大学获得硕士学位，主要从事光栅湿法刻蚀方面的研究。E-mail:jiangbeihaoge@126.com

焦庆斌(1986—)，男，辽宁丹东人，博士，助理研究员，2009年于大连民族学院获得学士学位，2014年于中国科学院长春光学精密机械与物理研究所获得博士学位，主要从事超声辅助湿法刻蚀等方面的研究。E-mail:voynichjqb@163.com

谭鑫(1981—)，男，吉林长春人，博士，研究员，博士生导师，2003年、2008年于中国科学技术大学分别获得学士、博士学位，主要从事光栅设计制作技术及光学器件微细加工技术的研究。E-mail:xintan_grating@163.com

巴音贺希格(1962—)，男，内蒙古鄂尔多斯人，博士，研究员，博士生导师，2004年于中国科学院长春光学精密机械与物理研究所获得博士学位，主要从事光栅理论、光栅制作技术及光谱技术的研究。E-mail:bayin888@sina.com

中图分类号: O436
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出版历程
- 收稿日期: 2018-10-29
- 修回日期: 2018-12-05
- 刊出日期: 2019-06-01

In-situ monitoring of metal depositing in the fabrication of metallic grating

ZHU Chun-lin^{1, 2
,},
HU Hao^{1, 2
,},
JIAO Qing-bin^1
,,
TAN Xin^1
,,
Bayanheshig^{1
, ,}

1.
Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China
2.
University of Chinese Academy of Sciences, Beijing 100049, China

Funds:

the National Natural Science Foundation of China(NSFC) 61227901

the National Natural Science Foundation of China(NSFC) 61605197

More Information

Corresponding author: Bayanheshig, E-mail:bayin888@sina.com

摘要

摘要: 在使用电铸方法制作金属光栅时，采用传统的计时电铸方法常常不能保证金属栅条具有精确的沉积厚度。为了能够实时监测光栅栅条的沉积厚度，以实现电铸截止时刻的精确判断，建立了基于衍射效率判断金属沉积厚度的在线监测系统。采用严格耦合波理论计算了Au在光刻胶沟槽中进行沉积时，衍射效率随Au沉积厚度的变化规律，并讨论了光刻胶占宽比、电铸电流密度对衍射效率的影响；计算了电铸池、镀液对监测金宝搏188软件怎么用能量造成的损耗。实验得到的效率曲线与仿真结果相一致；电铸池、镀液对光能的损耗达94.88%。实验结果表明，采用在线监测方法实时判断金属沉积厚度是合理有效的；光刻胶占宽比对在线监测影响不大；电铸电流密度对在线监测有影响，且电流密度越高越有利于截止点的判断。
- 金属光栅 /
- 在线监测 /
- 严格耦合波理论 /
- 占宽比 /
- 电流密度 /
- 能量损耗
Abstract: During the fabrication process of metallic gratings using electro-deposition, the thickness of deposited metal usually cannot be precisely controlled by the traditional timing method. In order to monitor the deposit thickness of grating bars and precisely stop depositing metal in a timely manner during the fabrication of metallic gratings, an in-situ monitoring system based on diffraction efficiency measurements was introduced. The change law of diffraction efficiency varying with Au deposition thickness was calculated using the rigorous coupled wave analysis(RCWA) method and the effect of the photoresistor grating's duty cycle and deposition current density on diffraction efficiency was discussed. The energy loss of monitoring lasers in the system was also calculated. The efficiency curve of the experiment coincides with simulation and the energy loss induced by the electro-deposition pool and solution was up to 94.88%. The experimental results indicate that the in-situ monitoring system is effective in estimating the thickness of deposited metal during the fabrication of metallic gratings. The duty cycle of photoresistor gratings has less influence on in-situ monitoring than that of deposition current density and a higher current density was more beneficial for monitoring.
- metallic grating /
- in-situ monitoring /
- RCWA /
- duty cycle /
- current density /
- energy loss

HTML全文

图 1 光刻胶光栅中电铸金属示意图

Figure 1. Diagram of depositing metal in photoresist grating

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图 2 +1级衍射效率与Au层沉积厚度、入射角度的关系

Figure 2. Relationship between +1^st order diffraction efficiency and thickness of Au and incident angle

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图 3 -1级衍射效率与Au层沉积厚度、入射角度的关系

Figure 3. Relationship between -1^st order diffraction efficiency and thickness of Au and incident angle

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图 4 零级衍射效率与Au层沉积厚度、入射角度的关系

Figure 4. Relationship between 0^th order diffraction efficiency and thickness of Au and incident angle

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图 5 45°角入射时零级衍射效率与Au层沉积厚度的关系

Figure 5. 0^th order diffraction efficiency varies with thickness of Au at 45° incident angle

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图 6 实验中零级光强度的变化

Figure 6. Changing of 0^th order efficiency in experiment

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图 7 监测光路示意图

Figure 7. Diagram of monitoring light

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图 8 光刻胶光栅显微镜照片

Figure 8. Microscope picture of photoresist grating

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图 9 不同占宽比下衍射效率随Au层沉积厚度的变化情况

Figure 9. Efficiency varies with thickness of Au under different duty cycles

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图 10 不同电流密度下Au电镀镀层照片

Figure 10. Photographs of Au electroplated coatings under different current densities

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图 11 棕红色镀层能谱图

Figure 11. Energy spectrum graph of brown electroplated surface

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图 12 不同放大倍率的低电流密度下镀层表面形貌

Figure 12. Surface morphologys with different magnifications under low current density

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图 13 不同放大倍率时高电流密度下镀层表面形貌

Figure 13. Surface morphologys with different magnifications under high current density

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图 14 不同聚集密度下衍射效率随Au镀层厚度的变化情况

Figure 14. Diffraction efficiency varies with thickness of Au under different accumulation densities

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