钝化
材料科学
硅
图层(电子)
针孔(光学)
氧化物
氧化硅
接口(物质)
硅太阳电池
光电子学
太阳能电池
接触角
复合材料
光学
氮化硅
冶金
坐滴法
物理
作者
Dongjin Choi,Haejung Lee,Dongkyun Kang,Hoyoung Song,MyeongSeob Sim,Yerin Lee,Youngho Choe,Yoonmook Kang,Donghwan Kim,Haeseok Lee,Hae-Seok Lee,Hae-Seok Lee
标识
DOI:10.1016/j.solmat.2024.113276
摘要
Tunnel oxide passivating contact (TOPCon) solar cells are characterized by high surface passivation and electrical transport efficiency due to the chemical passivation and field effect of the tunnel oxide and doped poly-silicon layers, respectively. Nevertheless, the passivation quality, implied open-circuit voltage (iV oc ), and device lifetime are adversely affected by high-temperature processing, leading to Auger recombination and pinhole defects in the tunnel oxide layer. This study aimed to explore the introduction of intrinsic poly-silicon as an interlayer to improve thermal stability and assesses its effect on the passivation of the tunnel oxide interface. Findings indicate that an intrinsic poly-silicon interlayer with a minimum thickness of 18 nm prevents passivation degradation at elevated temperatures. Additionally, the incorporation of this interlayer facilitates the tuning of the doping profile in crystalline silicon, resulting in a diminished pinhole density and an enhanced iV oc of 714.9 mV. These results advance our understanding of TOPCon solar cell performance and provide a foundation for their further optimization. • High temperatures affect tunnel oxide passivating contact (TOPCon) solar cells. • Intrinsic poly-silicon interlayer can improve thermal stability of TOPCon. • This interlayer with a minimum thickness of 18 nm prevents passivation degradation. • This layer facilitates the tuning of the doping profile in crystalline silicon. • The layer diminished the pinhole density and enhanced implied open-circuit voltage.
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