光伏系统
二极管
计算机科学
热传导
太阳能电池
材料科学
功率(物理)
频道(广播)
工作(物理)
软件部署
能量转换效率
互连
电源管理
光电子学
电子工程
热的
电
电气工程
工程物理
硅
智能电源
发电
热导率
纳米技术
底纹
工作温度
导电体
晶体硅
汽车工程
最大功率原理
太阳能
作者
Hanbo Tang,Yunpeng Li,Hao Lin,Chaowei Xue,Genshun Wang,Yongyuan Xu,Feng Ye,Liang Fang,Xixiang Xu,Pingqi Gao
标识
DOI:10.1038/s41467-026-70005-1
摘要
Partial shading is a common condition in the outdoor deployment of photovoltaic modules, potentially causing significant power loss and severe thermal damage. Limitations of existing solutions in balancing effect and cost necessitate a thorough solution, which involves a fundamental redesign at the solar cell level. Here we propose a cell architecture featuring integrated reverse conductivity to address this challenge. We derive the design principles by drawing inspiration from bypass diodes, and manage to introduce spatially uniform reverse conduction channels to the cell. These engineered in-cell channels exhibit bias-dependent switching behavior that enables reverse conductivity of the cell without compromising power conversion efficiency. The underlying mechanisms and modulation strategies of the cell are elucidated. Prepared photovoltaic modules composed of the proposed cells demonstrate clear advantages in thermal management and power output stability under partial shading conditions. The design principles and conduction channel strategies in this work also provide insight for other passivating-contact solar cells. The in-cell design approach offers merits in reliability, cost, and integration, and holds promise for next-generation photovoltaic technologies. Photovoltaic modules are susceptible to hot spots and output decline issue under partial shading. To address this challenge, Tang et al. report a silicon solar cell architecture with in-cell reverse conductivity channels, which mitigates thermal damage and stabilizes output without compromising power conversion efficiency
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