也從 56.67%提高至 88.76%,La 摻雜可使氧化亞銅薄膜往(111)面成長;
可見光平均穿透度由 43.28%增加至 50.41%,能隙由 2.54eV 增加至
參考文獻
[1]. M. Nolan, S. D. Elliott, “Tuning the Transparency of Cu
2
O withSubstitutional Cation Doping”, Chem. Mater., vol.20, 2002, pp.5522-5531.
[2]. C. G. Granqvist, A. Hultaker, “Transparent and conducting ITO films: new developments and applications”, Thin Solid Films, vol.411, 2002, pp.1-5.
[3]. S. Sugumaran, M. N. B. Ahmad, M. F. Jamlos, C. S. Bellan, S. Pattiyappan, R. Rajamani, R. K. Sivaraman, “Transparent with wide band gap InZnO nano thin film: Preparation and characterizations”, Optical Materials, vol.49, 2015, pp.348-356.
[4]. A. N. Banerjee, K. K. Chattopadhyay, P-Type Transparent Semiconducting
Delafossite CuAlO 2+X Thin Film: Promising Material For Optoelectronic Devices and Field-Emission Displays, Nova Science Publishers, Inc., 2007.
[5]. W. Y. Ching, Y. N. Xu, K. W. Wong, “Ground-state and optical properties of Cu
2
O and CuO crystals”, Phys. Rev. B, vol.40, 1989, p.7684.[6]. R. Restor, D. Schwarzenbach, “Charge density in cuprite, Cu
2
O”, Acta Cryst., B42, 1986, pp.201-208.[7]. D. O. Scanlon, B. J. Morgan, G. W. Watson and A. Walsh, “Acceptor Levels in p-Type Cu
2
O: Rationalizing Theory and Experiment”, Phys. Rev. Lett., vol.103, 2009, p.096405.[8]. A. F. Wright, J. S. Nelson, “Theory of the copper vacancy in cuprous oxide”, J. Appl. Phys., vol.92, 2002, p.5849.
[11]. H. Ohta, K. I. Kawamura, M. Orita, M. Hirano, “Current injection emission from a transparent p-n junction composed of p-SrCu
2
O2
/ n-ZnO”, Applied Physics Letters, vol.77, 2000, pp.475-477.[12]. A. A. Ogwu, T. H. Darma, E. Bouquerel, “Electrical resistivity of copper oxide thin films prepared by reactive magnetron sputtering ”, Journal of Achievements in Materials and Manufacturing Engineering, vol.24, 2007.
pp.172-177.
[13]. J. Gijsen, L. H. Tjeng, J. Van Elp, H. Eskes, J. Westerink, and G. A.
Sawatzky, “Electronic structure of Cu
2
O and CuO”, Physical review B, vol.38, 1988, pp.11322-11330.[14]. J. M. D. Cody, “Dilute magnetic oxides”, Current Opinion in Solid State and Materials Science, vol.10, 2006, pp.83-92.
[15]. C. Zhu, A. Osherov, M. J. Panzer, “Surface chemistry of electrodeposited Cu
2
O films studied by XPS”, Electrochimica Acta , vol.111 , 2013, pp.771-778.[16]. L. Pan, H. Zhu, C. Fan, W. Wang, Y. Zhang, J. Q. Xiao, “Mn-doped Cu
2
O thin films grown by rf magnetron sputtering”, J. Appl. Phys., vol.97, 2005, p.10D318.[17]. B. S. Li, K. Akimoto, A. Shen, “Growth of Cu
2
O thin films with high hole mobility by introducing a low-temperature buffer layer”, Journal of Crystal Growth, vol.311, 2009, pp.1102-1105.[18]. M. Izaki, T. Shinagawa, K. T. Mizuno, Y. Ida, M. Inaba, A. Tasaka,
“Electrochemically constructed p-Cu
2
O/n-ZnO heterojunction diode for photovoltaic device”, J. Phys. D: Appl. Phys., vol.40, 2007, pp.3326-3329.[19]. I. S. Brandt, C. A. Martins, V. C. Zoldan, A. D. C. Viegas, J. H. D. D. Silva, A. A. Pasa, “Structural and optical properties of Cu
2
O crystallineelectrodeposited films“, Thin Solid Films, vol.562, 2014, pp.144-151.
[20]. T. D. Golden, M. G. Shumsky, Y. Zhou, R. A. VanderWerf, R. A. V.
Leeuwen, J. A. Switzer, “Electrochemical Deposition of Copper(I) Oxide Films”, Chem. Mater., vol.8,1996, pp.2499-2504.
[21]. R. Umemura, M. Uehara, Y. Kimishima, “Investigation of Cu
2
O-Based Diluted Magnetic Semiconductor by Mechanical Milling”, Transactions of the Materials Research Society of Japan, vol.35, 2010, pp.247-250.[22]. S. Song, R. Rao, H. Yang, A. Zhang, “Cu
2
O/MWCNTs Prepared bySpontaneous Redox: Growth Mechanism and Superior Catalytic Activity”, J.
Phys. Chem. C, vol.114, 2010, pp.13998-14003.
[23]. X. Mathew, N. R. Mathews, P. J. Sebastian, “Temperature dependence of the optical transitions in electrodeposited Cu
2
O thin films”, Solar EnergyMaterials & Solar Cells, vol.70, 2001, pp.277-286.
[24]. A. O. Musa, T. Akomolafe, M. J. Carter, “Production of cuprous oxide, a solar cell material, by thermal oxidation and a study of its physical and electrical properties”, Solar Energy Materials and Solar Cells, vol.51, 1998, pp.305-316.
[25]. J. J. Loferski, “Theoretical Considerations Governing the Choice of the Optimum Semiconductor for Photovoltaic Solar Energy Conversion”, J.
Appl. Phys., vol.27, 1956, pp.777-784.
[26]. M. Kracht, J. Schörmann, M. Eickhoff, “Plasma assisted molecular beam epitaxy of Cu
2
O on MgO(001):Influence of copper flux on epitaxial orientation”, Journal of Crystal Growth, vol.436, 2016, pp.87-91.[29]. S. Nandy, A. N. Banerjee, E. Fortunato, R. Martins, “A Review on Cu
2
O and CuI
-Based p-Type Semiconducting Transparent Oxide Materials: Promising Candidates for New Generation Oxide Based Electronics”, Reviews in Advanced Sciences and Engineering, Vol.2, 2013, pp.1-32.[30]. 羅晏明,透明導電薄膜的功函數調變對光電特性之影,碩士論文,國立 雲林科技大學電子與光電工程研究所,2012 年。
[31]. 楊明輝,金屬氧化物透明導電材料的基本原理,工業材料,第179 期,
2001 年 11 月,第 134-144 頁.
[32]. A. Walsh, J. L. F. D. Silva, S. Wei, “Origins of band-gap renormalization in degenerately doped semiconductors”, Physical Review, vol.78, 2008,
p.075211.
[33]. L. Davis, “Properties of transparent conducting oxides deposited at room temperature”, Thin Solid Films, vol.236, 1993, pp.1-5.
[34]. M. Smith, V. Gotovac, L. Aljinovic, M. Lucic-Lavcevic, “An investigation of the electrochemical and photoelectrochemical properties of the cuprous oxide/liquid phase boundary”, Surface. Science, vol.335, 1995, pp.171-176.
[35]. K. Akimoto, S. Ishizuka, M. Yanagita, Y. Nawa, G. K. Paul, T. Sakurai,
“Thin film deposition of Cu
2
O and application for solar cell”, Solar Energy, vol.80, 2006, pp.715-722.[36]. A. Sivasankar and Reddy, “Properties of dc magnetron sputtered Cu
2
O films prepared at different sputtering pressures”, Applied Surface Science, vol.253, 2007, pp.5287-5292.[37]. 郭連騰,以常壓微波電漿法製備氧化亞銅薄膜,能源與光電鍍膜科技研 討會論文集,2007 年。
[38]. C. A. N. Fernando, P. H. C. de Silva, S. K. Wethasinha, I. M. Dharmadasa, T. Delsol, M. C. Simmonds, “Investigation of n-type Cu
2
O layers prepared by a low cost chemical method for use in photovoltaic thin solar cell”, Renewable Energy, vol.26, 2002, pp.521-529.[39]. 王玉芬、劉連城,石英玻璃,2007 年,第 10-30 頁。
Buonassisi, “Nitrogen-doped cuprous oxide as a p-type hole-transporting layer in thin-film solar cells”, J. Mater. Chem. A, vol.1, 2013, pp.15416-15422.
[43]. H. J. Li, C. Y. Pu, C. Y. Ma, Sh. Li, W. J. Dong, S. Y. Bao, Q. Y. Zhang,
“Growth behavior and optical properties of N-doped Cu
2
O films”, Thin Solid Films, vol.520, 2011, pp.212-216.[44]. X. Zheng, J. Li, Y. Zhou, “X-ray diffraction measurement of residual stress in PZT thin films prepared by pulsed laser deposition”, Acta Materialia, vol.52, 2004, pp.3313-3322.
[45]. A.K. Kulkarni, Kirk H. Schulz, T.S. Lim, M. Khan, “Dependence of the sheet resistance of indium-tin-oxide thin films on grain size and grain
orientation determined from X-ray diffraction techniques”, Thin Solid Films, vol.345, 1999, pp.273-277.
[46]. T. Nosaka, M. Yoshitake, A. Okamoto, S. Ogawa, Y. Nakayama, “Copper nitride thin films prepared by reactive radio-frequency magnetron
[49]. A. Wang, X. Li ,Y. Zhao, W. Wu, J. Chen, H. Meng, “Preparation and
characterizations of Cu
2
O/reduced graphene oxide nanocomposites with high photo-catalytic performances”, Powder Technology, vol.261, 2014, pp.42-48.[50]. G. Sahoo, S. R. Meher, M. K. Jain, “Room temperature growth of high crystalline quality Cu
3
N thin films by modified activated reactiveevaporation”, Materials Science and Engineering B, vol.191, 2015, pp.7-14.
[51]. S. Ghosh, F. Singh, D. Choudhary, D. K. Avasthi, V. Genevan, P. ShaH, A.
Gupta, “Effect of substrate temperature on the physical properties of copper nitride films by r.f. reactive sputtering”, Surface and Coatings Technology, vol.142-144, 2001, pp.1034-1039.
[52]. F. Hadian, A. Rahmati, H. Movla, M. khaksar, “Reactive DC magnetron sputter deposited copper nitride nano-crystalline thin films: Growth and characterization”, Vacuum, vol.86, 2012, pp.1067-1072.
[53]. J. F. Pierson, “Structure and properties of copper nitride films formed by reactive magnetron sputtering”, Vacuum, vol.66, 2002, pp.59-64.
[54]. Y. Nakano, S. Saeki, T. Morikawa, “Optical bandgap widening of p-type Cu
2
O films by nitrogen doping”, Appl. Phys. Lett., vol.94, 2009, p.022111.[55]. X. Lin, R. Zhou, J. Zhang, S. Fei, “A novel one-step electron beam irradiation method for synthesis of Ag/Cu
2
O nanocomposites”, Applied Surface Science, vol.256, 2009, pp.889-893.[56]. H. Nagai, T, Suzuki, H. Hara, C. Mochizuki, I. Takano, T. Honda, M. Sato,
“Chemical fabrication of p-type Cu
2
O transparent thin film using molecular precursor method”, Materials Chemistry and Physics, vol.137, 2012, pp.252-257.[57]. D. Trivich, E. Y. Wang, R. J. Komp, and A. S. Kakar, 13th IEEE Photovoltaic Specialist Conf. Proc., Washington DC, 1978, p.174.
[58]. N. A. Economou, R. S. Toth, R. J. Komp, and D. Trivich, 14th IEEE Photovoltaic Spec. Conf. Proc., New York, 1982, p.1180.
[59]. F. ANNA, Chemical Vapour Deposition of Undoped and Oxygen Doped Copper (I) nitride, 2010, Uppsala university , p.38.
[60]. G. Lai, Y. Wu, L. Lin, Y. Qu, F. Lai, “Low resistivity of N-doped Cu
2
O thin films deposited by rf-magnetron sputtering”, Applied Surface Science Part B, vol.285, 2013, pp.755-758.[61]. G. Haacke, “New figure of merit for transparent conductors”, J. Appl. Phys., vol.47, 1976, p.4086.