有機光伏材料之光電性質研究

Yun-Yue Lin; 林雲躍

Please use this identifier to cite or link to this item: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/35750

Full metadata record

???org.dspace.app.webui.jsptag.ItemTag.dcfield???	Value	Language
dc.contributor.advisor	陳俊維(Chun-Wei Chen)
dc.contributor.author	Yun-Yue Lin	en
dc.contributor.author	林雲躍	zh_TW
dc.date.accessioned	2021-06-13T07:08:11Z	-
dc.date.available	2009-07-30
dc.date.copyright	2005-07-30
dc.date.issued	2005
dc.date.submitted	2005-07-27
dc.identifier.citation	[1] Intergovernmental Panel on Climate Change(IPCC), “Third Assessment Report of Working Group I-Summary for Policy makers”,(2001) Web page:http://www.ipcc.ch/ [2] Wendy Uyen Huynh, University of California, Berkeley, PhD thesis, 2002. [3] REYNARD DL, ANDREW A, APPLIED OPTICS 5, 1, 23, 1966 [4] WITHEREL.PG, FAULHABE.ME, APPLIED OPTICS 9, 1, p73, 1970 [5] JAMES LW, MOON RL, APPLIED PHYSICS LETTERS 26, 8, p467-470, 1975 [6] DEBERNARDY R, DONAGHEY LF, JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 123, 8, C264-C264, 1976. [7] Yazawa Y, Tamura K, Watahiki S, SOLAR ENERGY MATERIALS AND SOLAR CELLS, 50 N 1-4, p229-235, 1998. [8] Matsubara H, Tanabe T, Moto A, et al, SOLAR ENERGY MATERIALS AND SOLAR CELLS, 50, N1-4, p177-184 1998. [9] Feteha MY, Eldallal GM, RENEWABLE ENERGY, 28, 7, p1097-1104, 2003. [10] Song DY, Aberle AG, Xia J, APPLIED SURFACE SCIENCE, 195, 1-4, p291-296, 2002. [11] Lee JC, Kang KH, Kim SK, et al, SOLAR ENERGY MATERIALS AND SOLAR CELLS, 64, 2, p185-195, 2000. [12] Ali S, Gharghi M, Sivoththaman S, et al, JOURNAL OF MATERIALS SCIENCE, 40, 6, p1469-1473, 2005. [13] Tucci M, de Cesare G, JOURNAL OF NON-CRYSTALLINE SOLIDS 338, p663-667, 2004. [14] Lee SH, Lee I, Yi J, SURFACE & COATINGS TECHNOLOGY, 153, 1, p67-71, 2002. [15] Budaguan BG, Sherchenkov AA, Stryahilev DA, JOURNAL OF THE ELECTROCHEMICAL SOCIETY , 145, 7, p2508-2512, 1998 [16] Morikawa H, Nishimoto Y, Naomoto H, SOLAR ENERGY MATERIALS AND SOLAR CELLS 53, 1-2, p23-28, 1998. [17] F. Gutmann and L.E. Lyons, Organic Semiconductors, Wiley, 1967, Chap. 8, P. 516. [18] H. Kallmann and M. Silver (eds.), Symposium on Electrical Conductivity in Organic Solids, Wiley-Inerscience, New York, 1961, pp. 39, 69, 291. [19] LEE CH, YU G, MOSES D, MOLECULAR CRYSTALS AND LIQUID CRYSTALS SCIENCE AND TECHNOLOGY SECTION A-MOLECULAR CRYSTALS AND LIQUID CRYSTALS, 256, p745-750, 1994. [20] Haugeneder A, Neges M, Kallinger C, PHYSICAL REVIEW B, 59, 23, p15346-15351 ,1999 [21] Coakley KM, McGehee MD, APPLIED PHYSICS LETTERS 83, 16, p3380-3382, 2003. [22] Brabec CJ, Cravino A, Meissner D, THIN SOLID FILMS 403, p368-372, 2002. [23] Kim H, Lee K, Park YG, JOURNAL OF THE KOREAN PHYSICAL SOCIETY 42, 1, p183-186, 2003. [24] Zhang FL, Johansson M, Andersson MR, SYNTHETIC METALS, 137, 1-3, p1401-1402 Part 2 Sp. Iss. SI, 2003. [25] Jun Gao, Fumitomo Hide, Hailiang Wang, Synthetic Metals, 84,p979-980, 1997. [26] N. C. Greenham, Xiaogang Peng, A. P. Alivisatos, Synthetic Metals, 84, p545-546, 1997. [27] J. J. Dittmer, R. Lazzaroni, Ph. Leclere, Solar Energy Materials & Solar Cells, 61, p53-61, 2000. [28] Anders Hagfeldt, Michael Gratzel, Accounts of Chemical Research, 33, p269-277, 2000. [29] Wedy U. Huynh, Janke J. Dittmer, William C. Libby, Advanced Functional Materials, 13, N1, p73-79, 2003. [30] A. Petrella, M. Tamborra, P. D. Cozzoli, Thin Solid Films, 451-452, p64-68, 2004. [31] C. Y. Kwong, A.B. Djuristic, P. C. Chui, Chemical Physical Letters, 384, p372-375, 2003. [32] Frederik C. Krebs, Jon E. Carle, Nicolaj Cruys-Bagger, Morten Anderson, Solar Energy Materials & Solar Cells, 86, p499-516, 2005. [33] Henry, J. Snaith, Ana C. Arias, Arne C. Morteani, Nanoletters, V2, N12, p1353-1357, 2002. [34] europa.eu.int/.../ nn/nn_rt/nn_rt_pv/images/ [35] Oliver Labeau, Philippe Tamarat, Brahim Lounis, Physical Review Letters, V90, N25, P257404, 2003. [36] Locklin J, Patton D, Deng SX, Baba A, Millan M, Advincula RC, CHEMISTRY OF MATERIALS, V16, N24, P5187-5193, 2004. [37] Koops HWP, Hoinkis OE, MICROELECTRONIC ENGINEERING, N57-8, P995-1001, 2001 [38] BOND SF, HOWIE A, FRIEND RH, SURFACE SCIENCE, 333, P196-200 Part A, 1995. [39] S.A. Crooker, T. Barrick, Applied Physical Letters, V82, N17, P2793, 2003. [40] C. K. Chiang, Y. W. Park, A. J. Heeger, The Journal of Chemical Physics, V69, I11, P5098-5104, 1978.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/35750	-
dc.description.abstract	本研究主要為探討有機-無機半導體材料混摻構成之光伏元件的基礎光電性質與元件結構設計，由於奈米材料具有獨特的量子效應與表面物理結構，因此當奈米結構的半導體與導電高分子混摻形成薄膜後，其介面間的反應以及載子的產生、傳導、以及結合等物理性質將是一個值得探討的主題。由於高分子材料成型性良好且製程簡單，因此搭配奈米粒子、奈米柱、奈米線等作為混摻的對象將有助於材料受光激發後產生的光電流效率以及傳輸的途徑，藉由控制奈米粒子的形態與尺寸可使得受光激發後的Exciton在擴散距離內即被分離成帶電電荷，而分子鏈的長短亦會影響Exciton能量的轉移與載子的傳輸，鏈與鏈的交互作用與交錯排列將可使帶電載子有連續性的傳導途徑◦	zh_TW
dc.description.abstract	In this thesis, the charge separation and transport efficiency of inorganic/organic hybrid photovoltaic material were studied. The unique quantum confinement and shape manipulation characteristic for nanoparticle can be utilized to fabricate photovoltaic device with special physical properties not observed in traditional silicon-base inorganic cell. Initial studies include optical properties of pristine MEH-PPV conducting polymer. Variation of the polymer concentration and molecular weight show that the PL and absorption spectrum red-shift with high solution concentration and high molecular weight. Exciton decay time is also influenced by interchain interaction. The interchain interaction could result in energy transfer and PL quench. We also study temperature dependence of blend system in dynamic and static measurements. The experiments show that at same temperature, PL spectra have red shift as the CdSe nanoparticle concentration increase in the polymer matrix. At low temperature, the absorption and PL spectrum also shift to long wavelength. These results can explain that the stacking order increase at low temperature and the increase in CdSe nanoparticle concentration also have similar effect. These phenomenons are interpreted by the increase in effective conjugated length. Effective conjugated length decreases while the temperature increases due to chain torsional motion. Therefore, increase in CdSe nanoparticle concentration would extend the effective conjugated length, and result in different Vibronic level transition decay time. Thin films photovoltaic device with varied CdSe nanoparticle concentration have significant improvement over pristine MEH-PPV device. This is consistent with charge separation efficiency improvement at high nanoparticle concentration. High nanoparticle concentration not only provides charge separation pathway, but also support efficiency electron transfer route. Also the short circuit current is proportional to CdSe concentration.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T07:08:11Z (GMT). No. of bitstreams: 1 ntu-94-R92527020-1.pdf: 5115748 bytes, checksum: ef18be0e721666a2b689cc49630da115 (MD5) Previous issue date: 2005	en
dc.description.tableofcontents	目錄摘要........................................................................................................................ I Abstract................................................................................................................II Acknowledgement............................................................................................. IV 目錄..................................................................................................................... VI 表目錄............................................................................................................. VIII 圖目錄................................................................................................................ IX Chapter 1 Introduction........................................................................................1 1.1 研究目的......................................................................................................1 1.2 文獻回顧......................................................................................................3 1.2.1 緒論.........................................................................................................3 1.3 研究動機......................................................................................................7 Chapter 2 Fundamental of Photovoltaic Device ...............................................9 2.1 導論................................................................................................................9 2.2 材料受光激發後的光伏特性....................................................................10 2.3 光伏元件性能與特性.................................................................................12 2.3.1 量子效率(Quantum Efficiency) ...........................................................16 2.3.2 能量轉換效率(Power Efficiency).........................................................16 2.3.3 頻譜響應(Spectral Response)...............................................................19 Chapter 3 General Properties of Conducting Polymer and Inorganic Nanomaterial......................................................................................23 3.1 緒論.............................................................................................................23 3.2 表面活性劑對II-VI 族半導體光電性質的影響......................................24 3.3 II-VI 族半導體奈米顆粒CdSe 的光學性質............................................26 3.4 導電高分子................................................................................................36 3.5 分子材料受光激發之物理性質................................................................38 3.6 載子在材料內的傳輸行為........................................................................39 3.7 分子量對材料的光學特性的影響............................................................41 3.8 溶劑濃度對材料光性的影響....................................................................45 3.9 MEH-PPV 在不同溫度下光譜的變化......................................................48 3.10 導電高分子的熱物理性質......................................................................55 Chapter 4 Optical Properties of Hybrid System .............................................59 4.1 混摻材料的光學性質.................................................................................59 Chapter 5. Hybrid II-VI Nanoparticle Conducting Polymer Bulk Heterojunction Photovoltaic Device...............................................73 Chapter 6 Conclusion ........................................................................................86 Reference ............................................................................................................88 Chapter 7 Appendices........................................................................................91
dc.language.iso	zh-TW
dc.subject	光電性質	zh_TW
dc.subject	奈米粒子	zh_TW
dc.subject	混摻	zh_TW
dc.subject	導電高分子	zh_TW
dc.subject	傳導	zh_TW
dc.subject	transport	en
dc.subject	Nanoparticle	en
dc.subject	conducting polymer	en
dc.subject	hybrid	en
dc.subject	charge separation	en
dc.title	有機光伏材料之光電性質研究	zh_TW
dc.title	Investigation of Optical and Electrical Properties of Organic Photovoltaic Materials	en
dc.type	Thesis
dc.date.schoolyear	93-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	林唯芳(Wei-Fang Su),戴子安(Chi-An Dai),江海邦(Hai.-Pang. Chiang)
dc.subject.keyword	奈米粒子,混摻,導電高分子,傳導,光電性質,	zh_TW
dc.subject.keyword	Nanoparticle,conducting polymer,hybrid,charge separation,transport,	en
dc.relation.page	102
dc.rights.note	有償授權
dc.date.accepted	2005-07-27
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	材料科學與工程學研究所	zh_TW
Appears in Collections:	材料科學與工程學系

Files in This Item:

File	Size	Format
ntu-94-1.pdf Restricted Access	5 MB	Adobe PDF

Show simple item record

DSpace JSPUI

DSpace preserves and enables easy and open access to all types of digital content including text, images, moving images, mpegs and data sets