光伏
材料科学
硅
光电子学
能量转换效率
多晶硅
晶体硅
载流子
工程物理
太阳能电池
光伏系统
纳米技术
电气工程
物理
工程类
图层(电子)
薄膜晶体管
作者
Armin Richter,Ralph Müller,Jan Benick,Frank Feldmann,Bernd Steinhauser,Christian Reichel,Andreas Fell,Martin Bivour,Martin Hermle,Stefan W. Glunz
出处
期刊:Nature Energy
[Springer Nature]
日期:2021-04-12
卷期号:6 (4): 429-438
被引量:279
标识
DOI:10.1038/s41560-021-00805-w
摘要
The photovoltaic industry is dominated by crystalline silicon solar cells. Although interdigitated back-contact cells have yielded the highest efficiency, both-sides-contacted cells are the preferred choice in industrial production due to their lower complexity. Here we show that omitting the layers at the front side that provide lateral charge carrier transport is the key to excellent optoelectrical properties for both-sides-contacted cells. This results in a conversion efficiency of 26.0%. In contrast to standard industrial cells with a front side p–n junction, this cell exhibits the p–n junction at the back surface in the form of a full-area polycrystalline silicon-based passivating contact. A detailed power-loss analysis reveals that this cell balances electron and hole transport losses as well as transport and recombination losses in general. A systematic simulation study led to some fundamental design rules for future >26% efficiency silicon solar cells and demonstrates the potential and the superiority of these back-junction solar cells. Front- and back-junction silicon photovoltaics dominate the market thanks to a lower manufacturing complexity compared with that of other device designs yet advances in efficiency remain elusive. Richter et al. now present an optimized design for the front and back junctions that leads to a 26.0%-efficient cell.
科研通智能强力驱动
Strongly Powered by AbleSci AI