Please use this identifier to cite or link to this item: http://hdl.handle.net/11455/8940
標題: 非晶矽/微晶矽疊層太陽電池之模擬研究
Simulation Study of Amorphous Silicon / Microcrystalline Silicon Tandem Solar Cell
作者: 吳金祐
Wu, Chin-Yu
關鍵字: Amorphous Silicon;非晶矽;Microcrystalline Silicon;Tandem Solar Cell;微晶矽;疊層太陽電池
出版社: 電機工程學系所
引用: [1]太陽電池 Solar Cells,黃惠良主編,五南出版社,2008。 [2]Spear W.E. and P.G. LeComber, Electronic proporties of substitutionally doped amorphous Si and Ge, Phil. Mag. 33, pp.935-949, 1976. [3]Triska, A., Dennison, D., and Fritzsche, H. “Hydrogen Content in Amorphous Ge and Si Prepared by RF Decomposition of GeH4 and SiH4“ Bulletin of American Physics Society, pp.20-392, 1975. [4]太陽電池技術入門,林明獻編著,全華出版社,2008。 [5]D. L. Staebler, C. R. Wronski, “Reversible conductivity changes in discharge - produced amorphous Si” Appl. Phys. Lett. 31.292, 1977. [6]奈米矽光電綠能科技,國家奈米實驗中心。 [7]Industrial Technology Research Institute. [8]Yamamoto, K., Materials Research Society.Proc.507, 1998. [9]J. Springer et al, Proc. 16th European Photovoltaic Solar Energy Conference, James & James Sci. Publ, pp.434, 2000. [10]SANYO Semiconductor Co.Ltd, http://sanyo.com/, 2010. [11]Y. Hamakawa, Recent Progress of Amorphous Silicon Solar Cell Technology, Proc. 6th International PVSEC, New Delhi, pp.3, 1992. [12]H. Tasaki et al., Computer Simulation Model of the Effects of Interface States on High Performance Amorphous Silicon Solar Cells, J. Appl. Phys., Vol.63, pp.500, 1988. [13]WALTER SCHOTTKY INSTITUT, http://www.wsi.tum.de/, 2010. [14]Ruud E.I. Schropp, Miro Zeman, Amorphous and Microcrystalline Silicon Solar Cells : Modeling Materials and Device Technology, 1998. [15]J. Zhao, A. Wang, P. Campbell, and M. A. Green, "A 19.8% efficient honeycomb multicrystalline silicon solar cell with improved light trapping", IEEE Trans. Electron Devices 46, pp. 1978, 1999. [16]Solar Cell Efficiency Tables (Version 33), Prog. Photovolt: Res. Appl. 2009; 17:85–94. [17]Fat Duen Ho,“SPICE MODELING OF CASCADE SOLAR CELLS”, in IEEE Proceedings of Southeastcon, vol.2, pp.776 -780, 1991. [18]S.O.Kasap, “Optoelectronics and photonics : principles and practices”, pp.256-257, 2001. [19]M.P. Thekackra, The Solar Cell Constant and Solar Spectrum Measurement from a Research Aircraft, NASA Technical Report No. R-351, 1970. [20]Silvaco ATLAS user manual, 2008. [21]Nagasaki shipyard, Machinery works “Microcrystalline High-Efficiency Tandem Solar Cell to Begin Production” Mitsubishi Heavy Industries, Ltd. Technical Review 44, 4, 2007. [22]Hamakawa,台北電能論壇發表,2004。 [23]Hetero-junction (HIT) silicon solar cell model for AMPS-1D simulation, Norberto Hernández-Como and Arturo Morales-Acevedo, 2008 5th International Conference on Electrical Engineering, Computing Science and Automatic Control, 2008.
摘要: 
在本篇論文中,主要是利用Silvaco TCAD模擬軟體,配合工研院(ITRI)太電中心實作樣本,來建構非晶矽、微晶矽與非晶矽/微晶矽疊層太陽電池之模擬模型,藉由建構與實作樣本有相同輸出特性的模擬模型,來觀察太陽電池特性的影響與變化。首先,在單層非晶矽與微晶矽太陽電池研究方面,先針對P層與N層的厚度、摻雜濃度,以及I層的厚度、摻雜濃度與缺陷能態密度,來觀察太陽電池主要參數的影響,從中了解相關的機制與特性。最後導入本論文研究的重點,非晶矽/微晶矽疊層太陽電池的研究,針對非晶矽與微晶矽吸收層的能隙和厚度分別進行調變,觀察轉換效率之變化,以獲得最佳化疊層太陽電池吸收層之能隙與厚度。

In order to establish the simulated model of the Amorphous Silicon Solar Cell, the Microcrystalline Silicon Solar Cell and the Amorphous/Microcrystalline Silicon Tandem Solar Cell, Silvaco TCAD simulated software combined with the real data of the ITRI Solar Cells is used in this study. Base on these Solar Cells models having the same outputted characteristics as the real Solar Cells, the influence and the variation of the Solar Cell characteristics are observed. Firstly, for the study of the Amorphous Silicon Solar Cell and the Microcrystalline Silicon Solar Cell, the thickness, the doping concentration and the density of states of the P-I-N Solar Cells are changed. The related affect and characteristics from the experimental data of the study are understood. Finally, the study focuses on the Amorphous/Microcrystalline Silicon Tandem Solar Cell, whose energy gap and the thickness of the absorptive layer are changed. The best energy gap and the best thickness of the absorptive layer of the Tandem Solar Cell from the variation data of the conversion efficiency of the Tandem Solar Cell are obtained.
URI: http://hdl.handle.net/11455/8940
其他識別: U0005-2506201022262200
Appears in Collections:電機工程學系所

Show full item record
 

Google ScholarTM

Check


Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.