Enhanced Optical Absorption of Amorphous Silicon Films by Ag Nanostructures 被引量：2

Enhanced Optical Absorption of Amorphous Silicon Films by Ag Nanostructures

下载PDF

导出

摘要 The optical absorption of amorphous silicon （α-Si） films is enhanced by silver （Ag） nanostructures deposited on the films. The reflection at the long wavelength side of localized plasmon polaritons （LPPs） resonance originated from Ag nanostructures is significantly decreased, i.e. the optical absorption is enhanced. The results show that the average reflection value of the amorphous silicon films in the wavelength range of 900-1200 nm could be decreased by 11.4%. Moreover, the reduction of the reflection is found to be mainly dependent on the size of the Ag nanostructures, which is related to the island sizes, i.e. the LPP＇s resonance peak position. The optical absorption of amorphous silicon （α-Si） films is enhanced by silver （Ag） nanostructures deposited on the films. The reflection at the long wavelength side of localized plasmon polaritons （LPPs） resonance originated from Ag nanostructures is significantly decreased, i.e. the optical absorption is enhanced. The results show that the average reflection value of the amorphous silicon films in the wavelength range of 900-1200 nm could be decreased by 11.4%. Moreover, the reduction of the reflection is found to be mainly dependent on the size of the Ag nanostructures, which is related to the island sizes, i.e. the LPP＇s resonance peak position.

作者周冰李东升项略略杨德仁

机构地区 State Key Laboratory of Silicon Materials and Department of Materials Science and Engineering

出处《Chinese Physics Letters》 SCIE CAS CSCD 2010年第3期270-273,共4页 中国物理快报（英文版）

基金 Supported by the National Basic Research Program of China under Grant No 2007CB613403, and the Natural Science Foundation of Zhejiang Province （Y1080068）.

关键词 Condensed matter: electrical magnetic and optical Semiconductors Surfaces interfaces and thin films Nanoscale science and low-D systems Condensed matter: electrical, magnetic and optical Semiconductors Surfaces, interfaces and thin films Nanoscale science and low-D systems

分类号 TN304.12 [电子电信—物理电子学] TB383 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献24

1Wurfel P 2004 Physics of Solar Cells: From Principles to New Concepts (Berlin: Wiley).
2Bruton T M 2002 Solar Energy Mater. Solar Cells 72 3.
3Myong S Y, Sriprapha K et al 2008 Solar Energy Mater. Solar Cells 92 639.
4Shah A V, Schade H, Vanecek Met al 2004 Prog. Photovoltaics. 12 113.
5Fahr S, Rockstuhl C and Lederer F 2008 Appl. Phys. Lett. 92 171114.
6Heine C, Morf R H and Gale M T 1996 J. Mod. Opt. 43 1371.
7Bielawny A, Upping J, Miclea P T, Wehrspohn R B et al 2008 Phys. Status Solidi A 205 2796.
8Zeng L, Bermel P, Yi Y, Alamariu B A, Broderick K A, Liu J, Hong C, Duan X et al 2008 Appl. Phys. Lett. 93 221105.
9Schaadt D M, Feng B and Yu E T 2005 Appl. Phys. Lett. 86 063106.
10Hagglund C, Zach M, Petersson G and Kasemo B 2008 Appl. Phys. Lett. 92 053110.

同被引文献2

1BAI YiMing 1 ,WANG Jun 2 ,CHEN NuoFu 1,3 ,YAO JianXi 1 ,YIN ZhiGang 3 ,ZHANG Han 3 , ZHANG XingWang 3 ,HUANG TianMao 3 ,WANG YanShuo 3 &YANG XiaoLi 3 1School of Renewable Energy Engineering,North China Electric Power University,Beijing 102206,China,2 National Engineering Research Center for Optoelectronic Devices,Institute of Semiconductors, Chinese Academy of Sciences,PO Box 912,Beijing 100083,China,3 Key Laboratory of Semiconductor Materials Science,Institute of Semiconductors, Chinese Academy of Sciences,PO Box 912,Beijing 100083,China.Quantifying the effectiveness of SiO_2/Au light trapping nanoshells for thin film poly-Si solar cells[J].Science China(Technological Sciences),2010,53(8):2228-2231. 被引量：4
2黄茜,张晓丹,王烁,曹丽冉,孙建,耿卫东,熊绍珍,赵颖.功能光学纳米Ag薄膜的制备及其光学特性研究[J].物理学报,2009,58(4):2731-2736. 被引量：2

引证文献2

1BAI YiMing,WANG Jun,YIN ZhiGang,CHEN NuoFu,ZHANG XingWang,FU Zhen,YAO JianXi,LI Ning,HE HaiYang,GULI MiNa.Ag nanoparticles preparation and their light trapping performance[J].Science China(Technological Sciences),2013,56(1):109-114. 被引量：2
2张宇杰,杨仕娥,陈永生,郜小勇,谷锦华,卢景霄.金属纳米颗粒光散射特性研究[J].太阳能学报,2017,38(3):721-725. 被引量：5

二级引证文献7

1高征,白一鸣,吴强,辛雅焜,何海洋,刘海,丁希宏,吴云召,王志斌,于晓琳,吕小颖,汪鼎民,陈诺夫.纳米颗粒表面等离激元在太阳电池中的应用[J].微纳电子技术,2013,50(9):551-558. 被引量：2
2延玲玲,白一鸣,刘海,陈吉堃,陈诺夫.FDTD优化a-Si∶H薄膜太阳电池Si_3N_4纳米柱陷光结构（英文）[J].微纳电子技术,2015,52(7):422-426.
3柯熙政,周茹.等离激元光电探测器的光吸收特性研究[J].激光与光电子学进展,2019,56(20):185-191. 被引量：2
4王霞.基于激光散射的超细颗粒粒度分布测定仿真[J].计算机仿真,2020,37(12):435-439. 被引量：1
5李娜,游剑.载血卟啉单甲醚中空金纳米球的光热光动力联合抗肿瘤研究[J].中国现代应用药学,2020,37(21):2617-2624. 被引量：3
6姚宇波,张丽平,刘文柱,石建华,孟凡英,刘正新.不同背反射结构在硅异质结太阳电池中的应用研究[J].太阳能学报,2022,43(10):37-42. 被引量：1
7于晓晨,李佳玉,杨振宇.量子尺度下Ag纳米颗粒吸收散射特性建模及分析[J].太阳能学报,2023,44(5):239-245.

1韩桂林,韩坤.无定形硅薄膜在静电复印技术中的应用[J].感光材料,1994(2):46-47.
2张磊,莫兰,沈晶晶,张颖,汪联辉.等离子激元纳米颗粒组装及其生物应用[J].科学通报,2016,61(27):3036-3048. 被引量：2
3徐森元,郑标,林林,冯卓宏,王哲哲,郑志强.银纳米立方颗粒表面等离子激元增强β-NaYF_4∶Er^(3+),Yb^(3+)上转换的研究[J].人工晶体学报,2016,45(3):649-654. 被引量：2
4马世杰,任云星,王大伟.集成电路封装中低压等离子清洗及其应用[J].山西电子技术,2016(3):44-46. 被引量：3
5卢有祥（译自）,季旭东（校对）.无定形硅TFT AMOLED器件[J].光电技术,2007,48(2):36-40.
6三星1．98英寸高清晰度液晶屏[J].数字通信,2006,33(18):17-17.
7黄碧琳,王云珍.用掺氧无定型硅减小平面半导体器件的表面电场[J].上海半导体,1991(3):46-52.
8季旭东.三星发布首款7英寸单芯片无定形硅LCD显示屏[J].光电技术,2007,48(4):43-43.
9Zhu Yabin Wang Zhiguang Sun Jianrong Yao Cunfeng Shen Tielong Chang Hailong Li Bingsheng Wei Kongfang Pang Lilong Sheng Yanbin Cui Minghuan Zhang Hongpeng Li Yuanfei Wang Ji Zhu Huiping.Micro-raman Study on a-Si, nc-Si and c-Si irradiated by 6 MeV Bi-ions[J].IMP & HIRFL Annual Report,2011(1):78-79.
10闫许,冯飞,张进,王跃林.Smooth Surface Morphology of Hydrogenated Amorphous Silicon Film Prepared by Plasma Enhanced Chemical Vapor Deposition[J].Plasma Science and Technology,2009,11(5):569-575. 被引量：1

Chinese Physics Letters

2010年第3期

浏览历史

内容加载中请稍等...

Enhanced Optical Absorption of Amorphous Silicon Films by Ag Nanostructures 被引量：2

参考文献24

同被引文献2

引证文献2

二级引证文献7

相关作者

相关机构

相关主题

浏览历史