多晶PERC太阳电池的背面与正面结构性能优化

Optimization of the Structure and Performance of Back and Front of Multicrystalline Si PERC Solar Cells

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摘要多晶硅太阳电池以其价格低廉的优势成为低成本太阳电池的首选,但其光电转换效率提升空间有限。钝化发射极和背面电池(PERC)技术是当前晶硅太阳电池提效的主要途径。多晶PERC电池结合了多晶硅电池的低成本和PERC电池的高效,是当前多晶硅电池的研究热点。本文研究了多晶PERC电池的背面和正面结构优化与设计,提出了提高多晶PERC电池效率的产业化技术方法。通过在硅片背面用三层SiNx:H薄膜来代替常规双层SiNx:H薄膜,在保证优良的背面钝化的同时,使电池长波响应得到改善,电池光电转换效率由20.19%提升至20.26%。优化多晶PERC电池的背面激光开窗工艺,使多晶电池效率较常规工艺提升0.11%。而在多晶PERC电池的正面叠加选择性发射极技术,可较常规工艺提升电池效率0.10%。综合运用多种提效手段有利于保持多晶PERC电池的竞争力。 The multicrystalline silicon(mc-Si)solar cells have become the first choice of low-cost solar cells due to their low price,while the room for improving their photoelectric conversion efficiency is limited.Passivated emitter and rear cell(PERC)is the main technology for improving the efficiency of Si solar cells.Combing the low cost of mc-Si solar cells and high efficiency of PERC,the mc-Si PERC is paid more attention recently.A series of technologies based on the back and front structures optimization of mc-Si PERCs were studied for high efficiency and mass production in the present work.By employing layers of AlOx/triple-SiNx:H on the rear of mc-Si wafers,the long wavelength spectral response was strengthened while the rear surface passivation was keeping,and the average efficiency of PERC with AlOx/triple-SiNx:H layers was increased to 20.26%from the standard mc-Si PERC of 20.19%.The efficiency of the battery was improved by 0.11%through optimizing the rear electrode contacting patterns by laser ablation,compared with the standard mc-Si PERC.The efficiency increased by 0.10%when introducing selective emitter technology on the front of mc-Si PERC.The comprehensive applications of different methods for improving efficiency benefit to the competitiveness of mc-Si PERC.

作者赵科巍张波吕镱庄宇峰李正平鲁贵林沈文忠 ZHAO Ke-wei;ZHANG Bo;LV Yi;ZHUANG Yu-feng;LI Zheng-ping;LU Gui-lin;SHEN Wen-zhong(Shanxi Lu’an Solar Energy Science and Technology Co.,Ltd.,Changzhi 046000,Shanxi,China;Institute of Solar Energy,and Key Laboratory of Artificial Structures and Quantum Control(Ministry of Education),School of Physics and Astronomy,Shanghai Jiao Tong University,Shanghai 200240,China)

机构地区山西潞安太阳能科技有限责任公司上海交通大学物理与天文学院

出处《新能源进展》 2020年第5期428-433,共6页 Advances in New and Renewable Energy

基金山西省重点研发计划项目(201803D421097,201903D121019)。

关键词太阳电池多晶硅电池长波响应 SiNx:H薄膜选择性发射极激光开窗 solar cells multicrystalline solar cells long wavelength spectral response SiNx:H thin film selective emitter laser ablation

分类号 TK514 [动力工程及工程热物理—热能工程] O472 [理学—半导体物理]

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参考文献4

1庞恒强.激光掺杂制作选择性发射极晶体硅PERC电池的工艺研究[J].材料导报,2018,32(A02):21-29. 被引量：7
2宋帅迪,赵广全,杨冬琴,张竹青,王强.低损伤选择性发射极太阳电池激光工艺[J].半导体技术,2019,44(11):893-898. 被引量：4
3贾河顺,王明利,任现坤,张黎明,刘鹏,姜言森,程亮,徐振华,李刚,张春艳.双层氮化硅薄膜对晶硅太阳电池性能的影响[J].太阳能学报,2014,35(10):2004-2008. 被引量：2
4马红娜,赵学玲,张红妹.激光掺杂制作选择性发射极电池扩散工艺的研究[J].光电子技术,2016,36(4):270-273. 被引量：2

二级参考文献18

1屈盛,陈庭金,刘祖明,廖华.太阳电池选择性发射极结构的研究[J].云南师范大学学报（自然科学版）,2005,25(3):21-24. 被引量：9
2郝晓光,王安亭,周世平,周凯.太阳能电池及金属化材料的现状及发展趋势[J].化工新型材料,2006,34(9):37-39. 被引量：6
3Fukui K, Okada K, Inomata Y, et al. Surface and bulk-passivated large area multicrystalline silicon solar cells [ J ]. Solar Energy Materials and Solar Cells, 1997, 48(1-4): 219-228.
4Filip Duerinckx, Jozef Szlufcik, Andrzej Ziebakowski, et al. Simple and efficient screen printing processes for multicrystalline silicon solar cells based on firing through silicon nitride [ A ]. Proceedings of the 14^th European Photovohaic Solar Energy Conference [ C ], Leuven Belgium, 1997, 792-795.
5Aberle A G. Crystalline silicon solar cells: Advanced surface passivation and analysis [ M ]. Australia: Bloxham and Chambers Pty Ltd, 1999, 18-20.
6Aberle Amain G, Hezel Rudolf. Progress in low temperature surface passivation of silicon solar ceils using remote-plasma silicon nitride [ J ]. Progress in Photovoltaics, 1997, 5 ( 1 ) : 29-50.
7Dastgheib-Shirazi A, Book F, Haverkam P H, et al. Investigations of high refractive silicon nitride layers for etched back emitters: Enhanced surface passivation for selective emitter concept [ A ]. Proceedings of the 24th European Photovoltaic Solar Energy Conference [ C ]. Hamburg, 2009, 1600-1604.
8Lee J Y, Glunz S W. Investigation of various surface passivation schemes for silicon solar cells [ J ]. Solar Energy Materials and Solar Cells, 2006, 90 ( 1 ) : 82- 92.
9Hofmann M, Kambor S, Schmidt C, et al. PECVD- ONO: A new deposited firing stable rear surface passivation layer system for crystalline silicon solar cells [ J ]. Advances in Opto Electronics, 2008, ( 1 ) :ID485467-485476.
10Guillevin N, Burgers A R, Geerligs L J, et al. ECN n-type silicon solar cell technology: An industrial process that yields 18. 5% [ A ]. Proceedings of the 34th IEEE Photovoltaie Specialists Conference (PVSC) [C], Petten, Netherlands, 2009, 990-992.

共引文献7

1宋帅迪,赵广全,杨冬琴,张竹青,王强.低损伤选择性发射极太阳电池激光工艺[J].半导体技术,2019,44(11):893-898. 被引量：4
2孙晓凯,田凤美,靳迎松,张福庆,胡明强.双面PERC太阳电池背面效率及双面率优化工艺[J].半导体技术,2020,45(4):312-316.
3韦瑶,黄红娜,刘旭,吕鹏飞,李严明.激光参数对“SE+PERC”单晶硅太阳电池电性能的影响[J].太阳能,2022(7):59-67. 被引量：1
4吴翔,高嘉庆,屈小勇,李跃恒,刘洪东.n型IBC太阳电池选择性背表面场工艺[J].微纳电子技术,2022,59(11):1234-1241.
5李雪方,韩超,申开愉.氧化硅膜对激光掺杂SE电极的保护性能研究[J].山西化工,2023,43(1):19-20.
6陈丹,屈小勇,高嘉庆,吴翔,王永冈,石惠君.局部掺杂选择性发射极对太阳电池电性能的影响[J].材料导报,2024,38(S02):11-14.
7张继禄,李家栋,舒华富,刘江,吴燕,李灵芝,鲁章波.TOPCon太阳电池复合钝化层参数对抗紫外能力的影响[J].半导体技术,2025,50(10):1013-1019.

1黄国平,王丽婷,邱家梁,黄惜惜,周肃,贾佳,李菁楠.基于激光掺杂的SE+PERC单晶硅太阳电池关键工艺的研究[J].太阳能,2020(9):31-37. 被引量：4
2王进财.浅谈晶硅电池刻蚀去PSG工序过刻情况[J].中国设备工程,2019,0(24):134-135.
3林映生,张伟伟,石学兵,潘湛昌,胡光辉.多层刚挠结合板层压质量改善[J].印制电路信息,2020,28(4):39-42. 被引量：2
4孙晓凯,田凤美,靳迎松,张福庆,胡明强.双面PERC太阳电池背面效率及双面率优化工艺[J].半导体技术,2020,45(4):312-316.
5庞恒强,周雨,贺茂双,王凯辉,常辉东,卞涛,薛凯.背面局域点接触对PERC太阳电池性能的影响[J].太阳能,2020(10):43-52. 被引量：2
6张婷,刘大伟,宋志成,倪玉凤,杨露,刘军保.多晶硅绕镀层的去除工艺研究[J].人工晶体学报,2020,49(9):1641-1645. 被引量：2

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多晶PERC太阳电池的背面与正面结构性能优化

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