局域表面等离子体增强锗的光电响应特性

doi:10.12066/j.issn.1007-2861.1816

上海大学学报(自然科学版) ›› 2018, Vol. 24 ›› Issue (2): 207-216.doi: 10.12066/j.issn.1007-2861.1816

局域表面等离子体增强锗的光电响应特性

齐功民¹^,²^,³, 狄增峰³, 任伟¹^,²()

1. 上海大学理学院, 上海 200444
2. 上海大学量子与分子结构国际中心, 上海 200444
3. 中国科学院上海微系统与信息技术研究所信息功能材料国家重点实验室, 上海 200050

收稿日期:2016-05-17 出版日期:2018-04-30 发布日期:2018-05-07
通讯作者: 任伟 E-mail:renwei@shu.edu.cn
基金资助:
国家自然科学基金资助项目(61475180);国家自然科学基金资助项目(11204340);国家自然科学基金资助项目(1127422);国家重点基础研究发展计划(973 计划)青年科学家计划资助项目(2015CB921600);上海市科委启明星计划资助项目(14QA1402000)

Photoelectric-response enhancement of local surface plasmon in Ge

QI Gongmin¹^,²^,³, DI Zengfeng³, REN Wei¹^,²()

1. College of Sciences, Shanghai University, Shanghai 200444, China
2. International Centre for Quantum and Molecular Structures, Shanghai University, Shanghai 200444, China
3. State Key Laboratory of Functional Materials for Informatics, Institute of Microsystem and Information Technology, Chinese Academy of Sciences, Shanghai 200050, China

Received:2016-05-17 Online:2018-04-30 Published:2018-05-07
Contact: REN Wei E-mail:renwei@shu.edu.cn

摘要/Abstract

摘要：

局域表面等离子体共振 (local surface plasmon resonance, LSPR) 因其对光独特的响应特性而在纳米光电子领域成为研究的重点. 作为重要的微电子材料, 锗在近红外波段的光电响应较弱, 而把局域表面等离子体应用在锗材料中, 必然会改善锗的光电响应特性. 利用时域有限差分 (finite difference time domain, FDTD) 法, 详细研究了 1, 2, 3 个银纳米颗粒嵌入锗中的消光光谱. 结果发现, 在可见光以及近红外比较宽的波长范围内, 这种复合结构可以有效增强锗的光电响应特性, 且多个孤立的银纳米颗粒会表现出与 1 个银纳米颗粒不一样的光电响应特性. 同时, LSPR 导致的光响应特性与光源的偏振、颗粒尺寸、颗粒个数以及颗粒之间的距离有依赖关系. 这一结果不仅对锗在光电子领域的应用有重要意义, 也可以拓宽局域表面等离子体在纳米光电子领域的应用范围.

关键词: 光电子, 局域表面等离子体共振, 时域有限差分法, 银纳米颗粒, 消光光谱

Abstract:

Local surface plasmon resonance (LSPR) is attracting much attention in nano-optoelectronics because of the unique photo response. Ge is an essential microelectronic material. But its photoelectric response is weak in the near-infrared region. Combination of the local surface plasmon and Ge can improve photoelectric response of Ge. The local surface plasmon resonance properties in Ge consisting of one, two and three silver nanoparticles cluster embedded in the Ge bulk are investigated using a finite difference time domain (FDTD) method. The extinction cross sections of one, two, and three silver nanoparticles are discussed in detail. The results show that the composite structure can effectively enhance extinction of Ge in a wide-range from visible to near-infrared. Moreover, the clusters show new types of photo responses as compared with single silver nanoparticle. The results also suggest that photo responses determined by local surface plasmon resonance depend strongly on conditions such as polarization directions of incident light, number of particles, size of single particle, and gap distances. This study is of significance for Ge applications and utilization of local surface plasmon resonance in optoelectronics.

Key words: optoelectronics, local surface plasmon resonance (LSPR), finite difference time domain (FDTD) method, silver nanoparticle, extinction cross section

中图分类号:

O436.2

齐功民, 狄增峰, 任伟. 局域表面等离子体增强锗的光电响应特性[J]. 上海大学学报(自然科学版), 2018, 24(2): 207-216.

QI Gongmin, DI Zengfeng, REN Wei. Photoelectric-response enhancement of local surface plasmon in Ge[J]. Journal of Shanghai University（Natural Science Edition）, 2018, 24(2): 207-216.

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参考文献 33

[1]	Nie S, Enmory S R. Probing single molecules and single nanoparticles by surface-enhanced[J]. Science, 1997,275(5303):1102-1106. pmid: 9027306
[2]	Warnes W L, Dereux A, Bobesen T W. Surface plasmon subwavelength optics[J]. Nature, 2003,424(6950):824-830. pmid: 12917696
[3]	Ma Y W, Wu Z W, Zhang L H, et al. Theoretical study of the local surface plasmon resonance properties of silver nanosphere clusters[J]. Plasmonics, 2013,8(3):1351-1360. doi: 10.1007/s11468-013-9541-y
[4]	Maier S A. Plasmonics: fundamentals and application[M]. New York: Springer, 2007.
[5]	Miller O D, Hsu C W, Reid M T H, et al. Fundamental limits to extinction by metallic nanoparticles [J]. Physical Review Letters, 2014, 112(12): 123903(1)-123903(5). pmid: 32639822
[6]	Kelly K L, Coronado E, Zhao L L, et al. The optical properties of metal nanoparticles: the influence of size, shape, and dielectric environment[J]. The Journal of Physical Chemistry B, 2003,107(3):668-677.
[7]	Shuford K L, Ratner M A, Schatz G C. Multipolar excitation in triangular nanoprisms [J]. The Journal of Chemical Physics , 2005, 123(11): 114713(1)-114713(9). pmid: 32640809
[8]	An K, Wei G, Qi G, et al. Stability improvement of C$_8$ H$_2$ and C$_{10}$ H$_2$ embedded in poly (vinyl alcohol) films with adsorption on gold nanoparticles[J]. Chemical Physics Letters, 2015,637:71-76.
[9]	Xu T N, Hu L, Jin S Q, et al. Photon energy conversion via localized surface plasmons in ZnO/Ag/ZnO nanostructures[J]. Applied Surface Science, 2012,258(15):5886-5891.
[10]	Liang Q, Yu W, Zhao W, et al. Numerical study of the meta-nanopyramid array as efficient solar energy absorber[J]. Optical Materials Express, 2013,3(8):1187-1196.
[11]	Cao S, Yu W, Wang T, et al. Two-dimensional subwavelength meta-nanopillar array for efficient visible light absorption [J]. Applied Physics Letters, 2013, 102(16): 161109(1)-161109(4). doi: 10.1063/1.4803444 pmid: 23696693
[12]	Schaadt D M, Feng B, Yu E T. Enhanced semiconductor optical absorption via surface plasmon excitation in metal nanoparticles [J]. Applied Physics Letters, 2005, 86(6): 063106(1)-063106(3).
[13]	Chen J, Wang D, Xi J, et al. Immuno gold nanocages with tailored optical properties for targeted photothermal destruction of cancer cells[J]. Nano Letters, 2007,7(5):1318-1322. pmid: 17430005
[14]	Hu M, Chen J, Li Z Y, et al. Gold nanostructures: engineering their plasmonic properties for biomedical applications[J]. Chemical Society Reviews, 2006,35(11):1084-1094. doi: 10.1039/b517615h pmid: 17057837
[15]	Lassiter J B, Aizpurua J, Hernandez L I, et al. Close encounters between two nanoshells[J]. Nano Letters, 2008,8(4):1212-1218. doi: 10.1021/nl080271o pmid: 18345644
[16]	Aubry A, Lei D Y, Maier S A, et al. Interaction between plasmonic nanoparticles revisited with transformation optics [J]. Physical Review Letters, 2010, 105(23): 233901(1)-233901(4). pmid: 21231490
[17]	Alaverdyan Y, Sepúlveda B, Eurenius L, et al. Optical antennas based on coupled nanoholes in thin metal films[J]. Nature Physics, 2007,3(12):884-889.
[18]	Wang G, Wang H, Cui Y, et al. Preparation of micro-sized and monodisperse crystalline silver particles used for silicon solar cell electronic paste[J]. Journal of Materials Science: Materials in Electronics, 2014,25(1):487-494.
[19]	Zhu J, Wang Y C, Lu Y M. Fluorescence spectra characters of silver-coated gold colloidal nanoshells[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2004,232(2):155-161.
[20]	Diao J J, Qiu F S, Chen G D, et al. Photoluminescence properties study of the Au/Au2S nanoshell[J]. Canadian Journal of Physics, 2002,80(6):707-711. doi: 10.1139/p02-047
[21]	Yee K S. Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media[J]. IEEE Transactions on Antennas and Propagation, 1966,14(3):302-307. doi: 10.1109/TAP.1966.1138693
[22]	Sullivan D M. Electromagnetic simulation using the FDTD method[M]. New York: John Wiley & Sons, 2013.
[23]	Tumbleston J R, Ko D H, Samulski E T, et al. Electrophotonic enhancement of bulk heterojunction organic solar cells through photonic crystal photoactive layer [J]. Applied Physics Letters, 2009, 94(4): 043305(1)-043305(3).
[24]	Hirigoyen F, Crocherie A, Vaillant J M, et al. FDTD-based optical simulations method-ology for CMOS image sensors pixels architecture and process optimization[C]//Electronic Imaging International Society for Optics and Photonics. 2008: 681609(1)-681609(12).
[25]	Chan D L C, Soljačić M, Joannopoulos J D. Thermal emission and design in 2D-periodic metallic photonic crystal slabs[J]. Optics Express, 2006,14(19):8785-8796. doi: 10.1364/oe.14.008785 pmid: 19529261
[26]	Hou B, Hang Z H, Wen W, et al. Microwave transmission through metallic hole arrays: surface electric field measurements [J]. Applied Physics Letters, 2006, 89(13): 131917(1)-131917(3). doi: 10.1063/1.2357553 pmid: 22942436
[27]	Bohren C F. How can a particle absorb more than the light incident on it?[J]. American Journal of Physics, 1983,51(4):323-327.
[28]	Bohren C F, Huffman D R. Absorption and scattering of light by small particles[M]. New York: John Wiley & Sons, 2008: 83-129.
[29]	Maier S A. Plasmonics: fundamentals and applications[M]. Berlin: Springer Science & Business Media, 2007.
[30]	Palik E D. Handbook of optical constants of solids [M]. Berlin: Academic Press, 1998: 351-479.
[31]	Maclean H J. Silver transport in CVD silicon carbide[D]. Boston: Massachusetts Institute of Technology, 2004: 23-77.
[32]	蔡光旭, 蒋昌忠, 任峰, 等. Ag 纳米颗粒的光吸收和透射电镜研究[J]. 武汉大学学报(理学版), 2007,53(5):589-592.
[33]	Atay T, Song J H, Nurmikko A V. Strongly interacting plasmon nanoparticle pairs: from dipole-dipole interaction to conductively coupled regime[J]. Nano Letters, 2004,4(9):1627-1631.

局域表面等离子体增强锗的光电响应特性

Photoelectric-response enhancement of local surface plasmon in Ge

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