Study on N-doped Cu2O Thin Film Fabricated by Low Temperature Deposition and Rapid Thermal Annealing
ZI Xingfa, YE Qing, LIU Ruiming, CHENG Man, HUANG Wenqing, HE Yongtai
Joint Research and Development Centre for New Energy Application Technology, School of Physical and Electronic Science, Chuxiong Normal University, Chuxiong 675000
Abstract: The N-doped Cu2O (Cu2O∶N) thin films were deposited by radio frequency magnetron sputtering a Cu2O target in N2 and Ar mixture atmosphere, and then the as-deposited Cu2O∶N thin films were annealed by rapid thermal annealing (RTA) in N2 atmosphere. Effects of N2 flow rates and annealing temperatures on growth behaviour, crystalline structures, surface morphologies,optical and electrical properties of Cu2O∶N thin films were investigated. The results showed that the as-deposited thin film grown at 300 ℃ substrate temperature contained only single phase of Cu2O under 12 sccm N2 flow rate. The RTA process had no influence on the crystalline structures of the as-deposited thin films in N2 atmosphere, but the crystalline quality of thin films could be sharply improved by rising annealing temperature (< 450 ℃). The thin film annealed at 400 ℃ showed good electrical properties—a Hall mo-bility (μ) of 27.8 cm2·V-1·s-1 and a resistivity (ρ) of 2.47×103 Ω·cm, which were attributed to the mitigated scattering of photo-generated carriers and the enhanced carriers transport, both induced by the improvement of crystalline quality and defect states of thin film as results of RTA. Our experiments indicated the effectiveness of low temperature sputtering deposition and RTA treatment on improving the photoelectric properties of Cu2O∶N thin films.
自兴发, 叶青, 刘瑞明, 程满, 黄文卿, 何永泰. N掺杂Cu2O薄膜的低温沉积及快速热退火研究*[J]. 《材料导报》期刊社, 2017, 31(16): 21-25.
ZI Xingfa, YE Qing, LIU Ruiming, CHENG Man, HUANG Wenqing, HE Yongtai. Study on N-doped Cu2O Thin Film Fabricated by Low Temperature Deposition and Rapid Thermal Annealing. Materials Reports, 2017, 31(16): 21-25.
1 Nandy S, Banerjee A, Fortunato E, et al. A review on Cu2O and CuI-based p-type semiconducting transparent oxide materials: Pro-mising candidates for new generation oxide based electronics [J].Rev Adv Sci Eng,2013,2(4):1.
2 Rühle S, Anderson A Y, Barad H N, et al. All-oxide photovoltaics [J].J Phys Chem Lett,2012,3(24):3755.
3 Yan X G, Huang W Q, Huang G F, et al. Band-gap widening of nitrogen-doped Cu2O: New insights from first-principles calculations [J]. Sci Adv Mater,2014,6(6):1221.
4 Alharbi F, Bass J D, Salhi A, et al. Abundant non-toxic materials for thin film solar cells: Alternative to conventional materials [J]. Renew Energy,2011,36(10):2753.
5 Minami T, Nishi Y, Miyata T. Heterojunction solar cell with 6% efficiency based on an n-type aluminum-gallium-oxide thin film and p-type sodium-doped Cu2O sheet [J]. Appl Phys Express,2015,8(2):022301-1.
6 Nishi Y, Miyata T, Minami T. Effect of inserting a thin buffer layer on the efficiency in n-ZnO/p-Cu2O heterojunction solar cells [J]. J Vac Sci Technol A,2012,30(4):04D103-1.
7 Minami T, Miyata T, Nishi Y. Efficiency improvement of Cu2O-based heterojunction solar cells fabricated using thermally oxidized copper sheets [J]. Thin Solid Films,2014,559(21):105.
8 Nishi Y, Miyata T, Minami T. The impact of heterojunction formation temperature on obtainable conversion efficiency in n-ZnO/p-Cu2O solar cells [J]. Thin Solid Films,2013,528(3):72.
9 Sohn J, Song Sanghun, Nam Dongwoo, et al. Effects of vacuum annealing on the optical and electrical properties of p-type copper-oxide thin-film transistors [J].Semicond Sci Technol,2013,28(1):15005.
10 Dimopoulos T, Pei′c A, Abermann S, et al. Effect of thermal annealing in vacuum on the photovoltaic properties of electrodeposited Cu2O-absorber solar cell [J]. EPJ Photovolt,2014,5:50301-1.
11 Lai Guozhong, Wu Yangwei, Lin Limei, et al. Low resistivity of N-doped Cu2O thin films deposited by rf-magnetron sputtering [J]. Appl Surf Sci,2013,285:755.
12 Ishizuka S, Okamoto Y, Akimoto K. Properties of polycrystalline Cu2O thin-films doped with N or Si as an acceptor dopant [J]. Solid Stata Phenomena,2003,93:313.
13 Ishizuka S, Kato S, Maruyama T, et al. Nitrogen doping into Cu2O thin films deposited by reactive radio-frequency magnetron sputtering [J]. Jpn J Appl Phys,2001,40(4):2765.
14 Li B B, Lin L, Shen H L, et al. Effect of N doping on hole density of Cu2O:N films prepared by the reactive magnetron sputtering method [J]. Eur Phys J Appl Phys,2012,58(2):20303.
15 Li H J, Pu C Y, Ma C Y, et al. Growth behavior and optical properties of N-doped Cu2O films [J]. Thin Solid Films,2011,520(1):212.
16 Zi Xingfa, Yang Wen, Yang Pengzhi, et al. Fabrication and optical properties of N-doping Cu2O thin films deposited by RF magnetron sputtering [J]. J Optoelectronics·Laser,2014,25(9):1727(in Chinese).
自兴发,杨雯,杨培志,等. RF磁控溅射制备N掺杂Cu2O薄膜及光学特性研究[J]. 光电子·激光,2014,25(9):1727.
17 Mittiga A, Salza E, Sarto F, et al. Heterojunction solar cell with 2% efficiency based on a Cu2O substrate[J]. Appl Phys Lett,2006,88(16):163502-1.
18 Noda S, Shima H, Akinaga H. Highly oriented polycrystalline Cu2O film formation using RF magnetron sputtering deposition for solar cells [J]. AIP Conf Proc,2014,1585:9.
19 Muñoz-Rojas D, Jordan M, Yeoh C, et al. Growth of 5 cm2·V-1·s-1 mobility, p-type copper(Ⅰ) oxide (Cu2O) films by fast atmospheric atomic layer deposition (AALD) at 225 ℃ and below [J]. AIP Adv,2012,2:042179-1.
20 Nakano Y, Saeki S, Morikawa T. Optical bandgap widening of p-type Cu2O films by nitrogen doping [J]. Appl Phys Lett,2009,94(94):022111-1.
21 Zi Xingfa, Huang Wenqing, Liu Ruiming, et al. Structural and optical properties of annealed Cu2O thin films [J]. J Optoelectronics·Laser,2015,26(10):1931(in Chinese).
自兴发,黄文卿, 刘瑞明,等. 退火Cu2O薄膜的结构及光学特性[J].光电子·激光,2015,26(10):1931.
22 Alnes M E, Monakhov E, Fjellva H, et al. Atomic layer deposition of copper oxide using copper(Ⅱ) acetylacetonate and ozone [J].Chem Vap Depos,2012,18(4):173.
23 Soumyo Chatterjee, Sudip K Saha, Amlan J Pal. Formation of all-oxide solar cells in atmospheric condition based on Cu2O thin-films grown through SILAR technique [J]. Solar Energy Mater Solar Cells,2016,147:17.
24 Ran Fanyong, Masataka Taniguti, Hideo Hosono, et al. Analyses of surface and interfacial layers in polycrystalline Cu O thin-film transistors [J]. J Disp Technol,2015,11(9):720.
25 Junqiang Li, Zengxia Mei, Lishu Liu, et al. Probing defects in nitrogen-doped Cu2O [J]. Sci Rep,2014,4(7240):1.
26 Nakano Y, Saeki S, Morikawa T. Optical bandgap widening of p-type Cu2O films by nitrogen doping [J]. Appl Phys Lett,2009,94(94):022111-1.
27 Yun Seog Lee, Jaeyeong Heo, Mark T Winkler,et al. Nitrogen-doped cuprous oxide as a p-type hole transporting layer in thin-film solar cells[J]. J Mater Chem A,2013,1:15416.
28 Asahi R, Morikawa T, Ohwaki T, et al. Visible-light photocatalysis in nitrogen-doped titanium oxides [J]. Science,2001,293(13):270.
渝公网安备50019002502923号 版权所有:《材料导报》编辑部
2017, Vol. 31 
