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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 劉致為(Chee Wee Liu) | |
dc.contributor.author | Jun Yu Chen | en |
dc.contributor.author | 陳俊宇 | zh_TW |
dc.date.accessioned | 2021-06-08T05:09:36Z | - |
dc.date.copyright | 2011-07-29 | |
dc.date.issued | 2011 | |
dc.date.submitted | 2011-07-22 | |
dc.identifier.citation | Chap.2
[1] I. Repins, M. A. Contreras, B. Egaas, C. DeHart, J. Scharf, C. L. Perkins, B. To, and R Noufi, Prog. Photovolt: Res. Appl. 16, 235 (2008). [2] R. Bacewicz, P. Zuk, and R.Trykozko, Opto-Electron Rev. 11, 277 (2003). [3] S. Siebentritt, in chapter 7 of Wide-Gap Chalcopyrites, Springer Series in Materials Science, edited by S. Siebentritt and U. Rau (Springer, New York, 2006). [4] S.-H. Han, F. S. Hasoon, H. A. Al-Thani, A. M. Hermann, and D. H. Levi, Appl. Phys. Lett. 85, 576 (2004). [5] J. E. Jaffe and A. Zunger, Phys. Rev. B 29, 1882 (1984). [6] M. Gloeckler, Device Physics Of Cu(In,Ga)Se2 Thin-Film Solar Cells, PhD thesis, Colorado State University, Fort Collins, Colorado (2005). [7] A. Jasenek and U. Rau, J. Appl. Phys., 90, 650 (2001). [8]T. Nakashiba, A. Yamada, L. Zhang, and M. Konagai, Conference on Optoelectronic and Microelectronic Materials and Devices, 281 (2008). [9] [10] P. D. Paulson, R. W. Birkmire, and W. N. Shafarman, J. Appl. Phys. 94, 879 (2003). [11] D. Liao and A. Rockett, J. Appl. Phys. 93, 9380 (2003). [12] H. Bayhan and A. S. Kavasoglu, Solar Energy 80, 1160 (2006). [13]C. -S. Jiang, F. S. Hasoon, H. R. Moutinho, H. A. Al-Thani, M. J. Romero, and M. M. Al-Jassim, Appl. Phys. Lett. 95, 127 (2003). [14] R. Kniese, D. Hariskos, G. Voorwinden, U. Rau, and M. Powalla, Thin Solid Films, 431 – 432, 543 (2003). [15] S. H. Liu, E. J. Simburger, J. Matsumoto, A. Garcia III, J. Ross, and J. Nocerino, Prog. Photovolt: Res. Appl. 13, 149 (2005). [16] S. Kijima and T. Nakada, Appl. Phys. Express 1, 075002 (2008). Chap.3 [1] I. Repins, M. A. Contreras, B. Egaas, C. DeHart, J. Scharf, C. L. Perkins, B. To, and R Noufi, “19•9%-efficient ZnO/CdS/CuInGaSe2 solar cell with 81•2% fill factor”, Progress in Photovoltaics: Research and Applications, vol. 16, pp. 235-239, 2008. [2] T. Tsuchiya, O. Tabata, J. Sakata, Y. Taga, “Specimen Size Effect on Tensile Strength of Surface Micromachined Polycrystalline Silicon Thin Films”, J. Microelectromech. Syst., vol. 7, pp. 106-113, 1998. [3] K. Matsunaga, T. Komaru, Y. Nakayama, T. kume, and Y. Suzuki, “Mass-production technology for CIGS modules”, Solar Energy Materials and Solar Cells, vol. 93, pp. 1134-1138, 2009. [4] M. Powalla, M. Cemernjak, J. Eberhardt, F. Kessler, R. Kniese, H.D. Mohring, B. Dimmler, “Large-area CIGS modules: Pilot line production and new developments”, Solar Energy Materials & Solar Cells 90 (2006) 3158–3164 [5] M. Passlack, Materials Fundamentals of Gate Dielectrics , Springer, The Netherlands, 2005, pp. 403. [6] R. Bacewicz, P. Zuk, and R. Trykozko, “Photoluminescence study of ZnO/Cds/Cu(In,Ga)Se2 solar cell”, OPTO-ELECTRONICS REVIEW, vol. 11, pp. 277-280, 2003. [7] N. M Terlinden, G. Dingemans, M. C. van de Sanden, and W. M. M. Kessels, “Role of field-effect on c-Si surface passivation by ultrathin (2-20 nm) atamic layer deposited Al2O3”, Applied Physics Letters, vol. 96, pp. 112101, 2010. [8] Sutichai CHAISITSAK, Akira YAMADA and Makoto KONAGAI ,'Preferred Orientation Control of Cu(In1-xGax)Se2 (x~0:28) Thin Films and Its Influence on Solar Cell Characteristics' , Jpn. J. Appl. Phys. Vol. 41 (2002) pp. 507–513 [9] Miguel A. Contreras, Manuel J. Romero, R. Noufi, 'Characterization of Cu(In,Ga)Se2 materials used in record performance solar cells', Thin Solid Films 511-512(2006)51–54 Chap.4 [1] D. L. Staebler and C. R. Wronski, ”Reversible conductivity changes in discharge-produced amorphous Si,” Appl. Phys Lett. 31, 1977, pp. 292-293. [2] A. Klaver et al., Solar Energy Materials & Solar Cells,92, pp050-60(2008). [3] D. E. Carlson and K. Rajan, “Evidence for proton motion in the recovery of light-induced degradation in amorphous silicon solar cells,” J. Appl. Phys. 83(3) 1998, pp. 1726-1729. [4] M. Stutzmann, W. B. Jackson, and C. C. Tsai, Phys. Rev. B., 32, 23 (1985) [5] J. H. Stathis and S. Zafar, Microelectronics Reliability, 46, 270 (2006) [6] K. Morigaki, Jpn. J. Appl. Phys, 27, 163 (1988) [7] Arvind Shah*, J. Meier, E. Vallat-Sauvain, C. Droz, U. Kroll, N. Wyrsch, J. Guillet, U. Graf, “Microcrystalline silicon and ‘micromorph’ tandem solar cells”, Thin Solid Films 403 –404 (2002) 179–187. [8] D. L. Staebler and C. R. Wronski, “Optically induced conductivity changes in discharge-produced amorphous silicon,” J. Appl. Phys. 51 1980, pp. 3262-3268. [9] D. E. Carlson and K. Rajan, “The reversal of light-induced degradation in amorphous silicon solar cells by an electric field,” Appl. Phys. Lett. 70(16). 21 April 1997. [10] Andreas Schenk and Ulrich Krumbein,'Coupled defect-level recombination:Theory and application to anomalous diode characteristics', J.Appl.Phys.75(5) [11] C. T. Sah, R. N. Noyce and W. Shockley, “Carrier generation and recombination in p-n junctions and p-n junction characteristics,” Proc.IRE, 45, p. 1228 (1957). | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/23745 | - |
dc.description.abstract | 本論文中,利用光激發光、外部量子效率和電壓電流量測去探討缺陷對銅銦硒鎵和非晶矽基薄膜太陽能電池的效應。
首先,銅銦鎵硒薄膜太陽能電池之光激發光特性顯示出與缺陷能階相關的躍遷,並可進一步分析出施體能階與受體能階。由於缺陷會造成銅銦鎵硒太陽能電池的短路電流溫度係數為負值,導致高溫下的效率變小。 在銅銦鎵硒薄膜太陽能電池製程上,需要很多到切割去完成,而這些粗糙切割都可能會在界面上產生許多複合中心。因此,我們試著利用原子層沉積技術在薄膜上沉積一層氧化鋁,以達到鈍化的效果。 在非晶矽基薄膜太陽能電池中,由於照光所產生的劣化是一個相當重要的課題。為了探討出非晶矽基薄膜太陽能電池的生命週期,我們做了一些可靠度的研究,另外,在利用施加外部偏壓的方式,讓原先由於照光所產生的劣化可以回復之前的效率。 | zh_TW |
dc.description.abstract | In this thesis, the photoluminescence, external quantum efficiency and J-V curve measurement are used to characterize defect information for Cu(In,Ga)Se2 and α-Si based thin film solar cells.
First, the photoluminescence of defect-related Cu(In,Ga)Se2 thin film solar cells show the donor-acceptor transition and band-impurity transition. The donor level and acceptor level can be extracted. The negative temperature coefficient of the short circuit current of Cu(In,Ga)Se2 solar cells may cause more degradation of power conversion efficiency at high temperature due to defects. In CIGS thin film solar cell standard process, it needs many patterning to complete process. The edge of the patterning is very rough and may have a lot of recombination in surface region. For the reason, atomic layer deposited (ALD) Al2O3 is used to passivated the CIGS and the effect of the passivation. For α-Si based solar cells, light-induced degradation is a significant issue. In order to investigate the lifetime of the α-Si based solar cells, we have to do reliability test. | en |
dc.description.provenance | Made available in DSpace on 2021-06-08T05:09:36Z (GMT). No. of bitstreams: 1 ntu-100-R98943107-1.pdf: 2314071 bytes, checksum: 3fb67b68cbe5f86346836194cec905c0 (MD5) Previous issue date: 2011 | en |
dc.description.tableofcontents | Contents
Chapter 1 Introduction 1.1 Motivation 1 1.2 Organization 1 Chapter 2 Defect related effect analysis of Cu(In,Ga)Se2 solar cells by photoluminescence 2.1 Introduction 3 2.2 Typical CIGS structure and experimental samples 3 2.3 Photoluminescence from CIGS solar cells 7 2.3.1 Pumping power dependence of PL 10 2.3.2 Temperature dependence of PL 12 2.4 Result and discussion 13 2.4.1 Temperature dependence of external quantum efficiency (EQE) 15 2.4.2 Temperature dependence of CIGS bandgap 17 2.5 Conclusion 19 References 20 Chapter 3 Surface passivation of Cu(In,Ga)Se2 by atomic layer deposited Al2O3 3.1 Introduction 22 3.2 Description of approach and techniques 23 3.3 Results and discussion 26 3.3.1 Photoluminescence from CIGS passivation films 26 3.3.2 Simulation of CIGS passivation films 29 3.3.3 XRD patterns of experimental samples 34 3.3.4 PL integrated intensity of experimental samples 37 3.4 Conclusion 38 References 39 Chapter 4 Recovery of light-induced degradation of α-Si based thin film solar cells by reverse bias 4.1 Introduction 41 4.2 Staebler-Wronski effect 41 4.3 Light-induced degradation and recovery method for α-Si based solar cells 44 4.4 Structure of experiment samples 46 4.5 Results and discussion 48 4.5.1 Degradation results and analysis 48 4.5.2 Recovery experiments and model of single junction solar cells 54 4.5.3 Recovery with different structure by reverse bias recovery application 59 4.5.4 Reliability of recovery experiments 63 4.6 Summary 64 References 65 Chapter 5 Summary and future work 5.1 Conclusion 67 5.2 Future work 68 List of Tables Table.3-1 The ratio of I(220)/ I(112) for co-evaporation CIGS films with and without deposition of Al2O3. 35 Table.3-2 The ratio of I(220)/ I(112) for co-evaporation CIGS films with and without annealing process. 37 Table.4-1 Recovery methods of light-induced degradation. 46 Table.4-2 The illuminated J-V data of experimental samples that with and without light-soaking. 53 Table.4-3 The illuminated J-V data of the α-Si solar cell after light soaking and the recovery by reverse bias 57 List of Figures Fig.2-1 The structure of typical CIGS solar cells. 5 Fig.2-2 The SEM image of CIGS solar cell (Sample 1). 5 Fig.2-3 The TEM image of CIGS solar cell (Sample 1). 6 Fig.2-4 The SEM image of CIGS solar cell (Sample 2). The CIGS layer has a thickness of 1.41μm. 6 Fig.2-5 The PL spectrum of Sample1 with 671 nm laser excitation at the power of 10mW. 9 Fig.2-6 The band diagram of CIGS energy states. ED = EC - 0.08eV and EA = EV + 0.03 eV. 10 Fig.2-7 The PL spectra of Sample1 with excitation power from 10 to 60mW 11 Fig.2-8 The PL spectra of Sample2 with excitation power from 15 to 60mW 11 Fig.2-9 The PL spectra of Sample1 with temperature range from 150 to 300K. 12 Fig.2-10 The PL spectra of Sample2 with temperature range from 150 to 300K. 13 Fig.2-11 The PL spectra of Sample1 (Two peaks: BI and DAP). 14 Fig.2-12 The PL spectra of Sample2 (One peak: BI). 14 Fig.2-13 The EQE spectra of Sample1. It shows obvious degradation at short wavelength region (< 1100nm) 16 Fig.2-14 The EQE spectra of Sample2. It shows slight degradation at short wavelength region and slight increased at long wavelength region. 16 Fig.2-15 The trapping mechanism of photo-generated carriers in CIGS solar cells. 17 Fig.2-16 The temperature dependence of the short circuit current (Jsc) of CIGS solar cells. The serious negative temperature coefficient of Sample1 is due to the defects to trap photo-generated carriers at high temperature. 18 Fig.3-1 Process sequence step of CIGS large-area module fabrication. 24 Fig.3-2 Process sequence schematic view of CIGS large-area module fabrication 24 Fig.3-3 Process sequence step of CIGS Samples in this study. 25 Fig.3-4 The PL spectrum of co-evaporation CIGS films at room temperature. The intensity of the film with 50nm thickness of Al2O3 as passivation layer has about 200 times larger PL intensity. 27 Fig.3-5 The band diagram of CIGS energy states 27 Fig.3-6 The PL spectrum of sputter CIGS films at room temperature. The intensity of the film with 50nm thickness of Al2O3 as passivation layer has about 20 times larger PL intensity. 28 Fig.3-7 The PL spectra of co-evaporation CIGS films with Al2O3 passivated with temperature range from 150 to 300K. 29 Fig.3-8 The relative integrated light intensity versus the Seff of CIGS with various bulk life time. 30 Fig.3-9 The energy band diagram of the CIGS film w/ and w/o Al2O3 as passivation layer. 31 Fig.3-10 The surface recombination velocity versus the Qf of CIGS with various Dit 32 Fig.3-11 Dit at the interface can be reduce to about half of the no passivation one 33 Fig.3-12 The simulation structure when CIGS is passivated by the Al2O3 33 Fig.3-13 The XRD patterns for co-evaporation CIGS films with and without deposition of Al2O3. 34 Fig.3-14 The XRD patterns for co-evaporation CIGS films with and without N2 annealing. 36 Fig.3-15 The XRD patterns for co-evaporation CIGS films with and without forming gas annealing. 36 Fig.3-16 Relative integrated PL intensity with different thickness of Al2O3, annealing time of N2 and forming gas. The light intensity increases with increasing thickness of Al2O3. 38 Fig.4-1 The efficiency of α-Si solar cells degrades after light-soaking. 43 Fig.4-2 The EQE of α-Si solar cells degrades after light-soaking. 43 Fig.4-3 The model of the Staebler-Wronski Effect. 44 Fig.4-4 Structure of experimental samples. (a)α-SiGe (b)α-Si (c)a-Si/ | |
dc.language.iso | en | |
dc.title | 銅銦鎵硒及非晶矽基薄膜太陽能電池之缺陷效應 | zh_TW |
dc.title | Defect Related Effects of CIGS and | en |
dc.type | Thesis | |
dc.date.schoolyear | 99-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 郭宇軒(Yu-Hsuan Kuo),張書通(Shu-Tong Chang),林中一(Lin Chung-Yi),張廖貴術(K.S. Chang-Liao) | |
dc.subject.keyword | 銅銦鎵硒,光激發光,外部量子效率,鈍化,非晶矽基太陽能電池, | zh_TW |
dc.subject.keyword | Cu(In,Ga)Se2,Photoluminescence,external quantum efficiency,passivation,α-Si based solar cells, | en |
dc.relation.page | 68 | |
dc.rights.note | 未授權 | |
dc.date.accepted | 2011-07-22 | |
dc.contributor.author-college | 電機資訊學院 | zh_TW |
dc.contributor.author-dept | 電機工程學研究所 | zh_TW |
顯示於系所單位: | 電機工程學系 |
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