基于氧化镍背接触缓冲层碲化镉薄膜太阳电池的研究

肖迪; 王东明; 李珣; 李强; 沈凯; 王德钊; 吴玲玲; 王德亮

doi:10.7498/aps.66.117301

摘要

采用电子束蒸发法制备了NiO薄膜，并对其作为碲化镉薄膜太阳电池背接触缓冲层材料进行了相关研究.NiO缓冲层的加入使得碲化镉太阳电池开路电压显著增大.通过X射线光电子能谱测试得到的NiO/CdTe界面能带图表明NiO和CdTe的能带匹配度很好.NiO是宽禁带P型半导体材料，在电池背接触处形成背场，减少了电子在背表面处的复合，从而提高电池开路电压.通过优化NiO薄膜厚度，制备得到转换效率为12.2%、开路电压为789 mV的碲化镉太阳电池.研究证实NiO是用来制备高转换效率、高稳定性碲化镉薄膜太阳电池的一种极有前景的缓冲层材料.

关键词:

Abstract

In this work, we report that NiO thin film can be used as a back contact buffer layer in CdTe thin film solar cells. The NiO layer is prepared by electron beam evaporation. To optimize the thickness of the NiO thin film, we fabricate some CdTe solar cells with different NiO thickness values. A NiO/Au back contact CdTe solar cell with an efficiency of 12.17% and an open-circuit voltage Voc of 789 mV is obtained, which are comparable to those of a standard Cu/Au back contact solar cell. The X-ray photoelectron spectroscopy (XPS) is used to quantitatively characterize the band alignment at the CdTe/NiO interface. It can be seen from the band alignment that the valence band offset (EVBO) is 0.52 eV and the conduction band offset (ECBO) is 2.68 eV. The EVBO presents no energy barrier for hole to transport from CdTe to NiO. The value of ECBO indicates that NiO can act as a back surface field layer (BSF) to dramatically reduce carrier recombination in the contact region of a CdTe cell, leading to an improved Voc. The band alignment obtained from XPS measurement shows that the band alignments of NiO and CdTe are perfectly matched. However, the conductivity of NiO film is poor. The insertion of a NiO buffer layer in the back contact increases the series resistance and reduces the fill factor (FF). We propose to use Cu/NiO composite structure as a bi-layer contact to improve the conductivity of the NiO buffer layer, which at the same time can be used to dope the CdTe film surface by Cu to obtain a low resistive contact. We fabricate a cell with a contact structure of 3-nm-Cu/20-nm-NiO/Au and the cell has a Voc of 796 mV, a Jsc (short-circuit currrent) of 24.2 mA/cm2, an FF of 70.2% and an efficiency of 13.5%. In order to study the stability of the solar cell with a Cu/NiO/Au back contact, a thermal stressing test is carried out at a temperature of 80 ℃ in the air atmosphere. For the Cu/NiO/Au back contact structure solar cell, the efficiency decreases from 13.1% to 12.9% after the cell is stressed for 80 h, showing that the stability of the Cu/NiO/Au back contact cell is significantly improved compared with that of the standard Cu/Au contact cell. In summary, the experimental results obtained in this study demonstrate that NiO thin film is a promising buffer layer for manufacturing stable and high efficiency CdTe thin film solar cells.

Keywords:

CdTe /
thin film solar cell /
NiO /
buffer layer

作者及机构信息

1.
中国科学技术大学, 合肥微尺度物质科学国家实验室(筹), 合肥 230026

通信作者: 王德亮, eedewang@ustc.edu.cn

基金项目: 国家自然科学基金（批准号：61474103，51272247）资助的课题.

Authors and contacts

1.
Hefei National Laboratory for Physical Sciences at the Microscale, University of Science and Technology of China, Hefei 230026, China

Corresponding author: Wang De-Liang, eedewang@ustc.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 61474103, 51272247).

参考文献

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[23]	Kim J H, Liang P W, Williams S T, Cho N, Chueh C C, Glaz M S, Ginger D S, Jen A K Y 2015 Adv. Mater. 27 695

施引文献

[1]	Britt J, Ferekides C 1993 Appl. Phys. Lett. 62 2851
[2]	Wu X Z 2004 Sol. Energy 77 803
[3]	Bai Z Z, Yang J, Wang D L 2011 Appl. Phys. Lett. 99 143502
[4]	Green M A, Emery K, Hishikawa Y, Warta W, Dunlop E D 2015 Prog. Photovolt Res. Appl. 23 1
[5]	Demtsu S H, Sites J R 2006 Thin Solid Films 510 320
[6]	Corwine C R, Pudov A O, Gloeckler M, Demtsu S H, Sites J R 2004 Sol. Energy Mater. Sol. Cells 82 481
[7]	Paudel N R, Yan Y F 2016 Prog. Photovolt Res. Appl. 24 94
[8]	Trck J, Nonnenmarcher H J, Connor P M L, Siol S, Siepchen B, Heimfarth J P, Klein A, Jaegermann W 2016 Prog. Photovolt Res. Appl. 24 1229
[9]	Yang R L, Wang D Z, Jeng M J, Ho K M, Wang D L 2016 Prog. Photovolt Res. Appl. 24 59
[10]	Phillips A B, Khanal R R, Song Z N, Zartman R M, DeWitt J L, Stone J M, Roland P J, Plotnikov V V, Carter C W, Stayancho J M, Ellingson R J, Compaan A D 2013 Nano Lett. 13 5224
[11]	Paudel N R, Xiao C X, Yan Y F 2015 Prog. Photovolt Res. Appl. 23 437
[12]	Paudel N R, Compaan A D, Yan Y F 2013 Sol. Energy Mater. Sol. Cells 113 26
[13]	Shen K, Yang R L, Wang D Z, Jeng M J, Chaudhary S, Ho K M, Wang D L 2016 Sol. Energy Mater. Sol. Cells 144 500
[14]	Ishikawa R, Furuya Y, Araki R, Nomoto T, Ogawa Y, Hosono A, Okamoto T, Tsuboi N 2016 Jpn. J. Appl. Phys. 55 02BF04
[15]	Liu S Y, Liu R, Chen Y, Ho S, Kim J H, So F 2014 Chem. Mater. 26 4528
[16]	Sonavane A C, Inamdar A I, Shinde P S, Deshmukh H P, Patil R S, Patil P S 2010 J. Alloys Compd. 489 667
[17]	Jung J W, Chueh C C, Jen A K Y 2015 Adv. Mater. 27 7874
[18]	Nahass M M E, Ismail M E, Hagary M E 2015 J. Alloys Compd. 646 937
[19]	Ai L, Fang G J, Yuan L Y, Liu N S, Wang M J, Li C, Zhang Q L, Li J, Zhao X Z 2008 Appl. Surf. Sci. 254 2401
[20]	Yin X T, Chen P, Que M D, Xing Y L, Que W X, Niu C M, Shao J Y 2016 ACS Nano 10 3630
[21]	Wang Z Y, Lee S H, Kim D H, Kim J H, Park J G 2010 Sol. Energy Mater. Sol. Cells 94 1591
[22]	Li J J, Diercks D R, Ohno T R, Warren C W, Lonergan M C, Beach J D, Wolden C A 2015 Sol. Energy Mater. Sol. Cells 133 208
[23]	Kim J H, Liang P W, Williams S T, Cho N, Chueh C C, Glaz M S, Ginger D S, Jen A K Y 2015 Adv. Mater. 27 695

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