这是超过 100 篇引用 SunSolve 结果的出版物之一。

Title
Development of TOPCon tunnel-IBC solar cells with screen-printed fire-through contacts by laser patterning
Abstract
Interdigitated back contact (IBC) solar cells featuring passivated contacts are promising candidates to achieve record-efficiency single-junction silicon-based solar cells. However, they usually require processes that are not amenable for industrial mass production and involve great process complexity associated with patterning and alignment. In this work, we present a novel TOPCon tunnel-IBC solar cell architecture, minimizing the complexity of patterning and alignment. By adopting a local poly-Si(n+)/poly-Si(p+)/SiOx tunnel junction, this cell architecture only requires full-area deposition of various thin-film layers and is compatible with conventional fire-through screen printing. The cell architecture is realized by sequential laser patterning steps and hence no shadow masks are needed. As a critical building block, we develop a working poly-Si(n+)/(SiOx)/poly-Si(p+)/SiOx tunnel junction with implied open-circuit voltage of 727 mV and a tunnel resistivity of 0.52 Ω cm2. We also establish the required laser patterning and damage-removal processes. Finally, we demonstrate that both the electron-selective and hole-selective regions can be contacted by conventional high-temperature fire-through screen printing, hence being compatible with industrial solar cell processing. Using realistic input parameters measured on test samples, we demonstrate by computer simulation that the proposed TOPCon tunnel-IBC cells favour IBC geometry with small pitches up to the technological limit. Corresponding full device integration is currently ongoing.
URL
出版机构
Author
Puqun Wang and Ranjani Sridharan and Xin Ren Ng and Jian Wei Ho and Rolf Stangl
Journal
Solar Energy Materials and Solar Cells
Keywords
All-back-contact solar cells,Industrial processes,Laser patterning,TOPCon,Tunnel junction,Tunnel-IBC
Year
2021
Month
1
DOI
10.1016/j.solmat.2020.110834
ISSN
09270248
Pages
110834
Publisher
Elsevier B.V.
Volume
220
所有出版 »

SunSolve Power

用于优化太阳能电池和组件设计的最先进仿真模拟平台。