Novel Passivation and Gettering Strategy for Silicon Wafer by Al2O3/n‐poly‐Si/SiOx Stack for High‐Efficiency p‐Type Passivating Tunnel Oxide Contact Solar Cells

Khokhar, Muhammad Quddamah; Yousuf, Hasnain; Chu, Mengmeng; Kim, Youngkuk; Jeon, Minsung; Dhungel, Suresh Kumar; Yi, Junsin

doi:10.1002/ente.202301031

Energy Tech

2024

DOI: 10.1002/ente.202301031

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Novel Passivation and Gettering Strategy for Silicon Wafer by Al₂O₃/n‐poly‐Si/SiO_x Stack for High‐Efficiency p‐Type Passivating Tunnel Oxide Contact Solar Cells

Muhammad Quddamah Khokhar,

Hasnain Yousuf,

Mengmeng Chu

et al.

Abstract: This study focuses on the enhanced passivation and gettering of boron‐doped p‐type solar grade silicon wafers by incorporating carrier‐selective and passivating tunnel oxide contact (TOPCon). A symmetrical stack of aluminum oxide (Al2O3)/p‐doped n‐type polysilicon (n‐poly‐Si)/ ultrathin silicon oxide (SiOx) in conjunction with long cycles of forming gas annealing is used for enhancing the silicon wafer quality with a novel approach. Multilayer of n‐poly‐Si/SiOx on p‐type crystalline silicon wafer exhibits an i… Show more

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Systematic Modeling and Optimization for High‐Efficiency Interdigitated Back‐Contact Crystalline Silicon Solar Cells

Khokhar,

Yousuf,

Alamgeer

et al. 2024

Energy Tech

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This study utilizes Quokka3, an advanced solar cell simulation program, specifically tailored for interdigitated back‐contact (IBC) crystalline silicon (c‐Si) solar cells. Through meticulous Quokka3 simulations, the influence of several geometric and wafer characteristics of the solar cell backside on current–voltage (I–V) performance has been scientifically explored for IBC c‐Si solar cells. The investigation encompasses parameters such as wafer thickness, bulk lifetime, resistivity, emitter and back surface field area fraction, and front‐ and rear‐surface passivation. Optimal values for these parameters have been proposed to enhance the efficiency of IBC solar cells. These recommendations contain an emitter percentage of 70%, a wafer thickness ranging from 200 μm, a wafer resistivity of 1 Ω cm, and a wafer bulk lifetime of at least 10 ms. Moreover, under conditions where the cell is not short‐circuited, the potential for achieving higher cell efficiency, up to 26.64%, has been shown.

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Systematic Modeling and Optimization for High‐Efficiency Interdigitated Back‐Contact Crystalline Silicon Solar Cells

Khokhar,

Yousuf,

Alamgeer

et al. 2024

Energy Tech

View full text Add to dashboard Cite

show abstract

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Novel Passivation and Gettering Strategy for Silicon Wafer by Al₂O₃/n‐poly‐Si/SiO_x Stack for High‐Efficiency p‐Type Passivating Tunnel Oxide Contact Solar Cells

Cited by 1 publication

References 66 publications

Systematic Modeling and Optimization for High‐Efficiency Interdigitated Back‐Contact Crystalline Silicon Solar Cells

Systematic Modeling and Optimization for High‐Efficiency Interdigitated Back‐Contact Crystalline Silicon Solar Cells

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