Analysis of the recombination mechanisms of a silicon solar cell with low bandgap-voltage offset

André Augusto; Stanislau Herasimenka; Richard King; Stuart Bowden; Christiana Honsberg

doi:10.1063/1.4984071

Analysis of the recombination mechanisms of a silicon solar cell with low bandgap-voltage offset

André Augusto, Stanislau Herasimenka, Richard King, Stuart Bowden, Christiana Honsberg

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Abstract

The mathematical dependence of bandgap-voltage offset on Auger and radiative recombination is derived. To study the recombination near the intrinsic limit, we manufacture thin silicon heterojunction test structures designed to minimize surface recombination, and to measure voltages and effective lifetimes near the Auger and radiative limit. Open-circuit voltages over 760 mV were measured on 50-μm-thick structures, leading to bandgap-voltage offsets at open-circuit down to 0.35 V. The Auger and radiative recombination represents over 90% of the recombination at open-circuit. This dominance also holds at the maximum power point, giving pseudo-fill factors of 86%. We demonstrate the potential of thin silicon devices to reach high voltages, and bandgap-voltage offsets in line with the best reported for direct bandgap materials such as gallium indium phosphide and gallium arsenide.

Original language	English (US)
Article number	205704
Journal	Journal of Applied Physics
Volume	121
Issue number	20
DOIs	https://doi.org/10.1063/1.4984071
State	Published - May 28 2017

ASJC Scopus subject areas

Physics and Astronomy(all)

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title = "Analysis of the recombination mechanisms of a silicon solar cell with low bandgap-voltage offset",

abstract = "The mathematical dependence of bandgap-voltage offset on Auger and radiative recombination is derived. To study the recombination near the intrinsic limit, we manufacture thin silicon heterojunction test structures designed to minimize surface recombination, and to measure voltages and effective lifetimes near the Auger and radiative limit. Open-circuit voltages over 760 mV were measured on 50-μm-thick structures, leading to bandgap-voltage offsets at open-circuit down to 0.35 V. The Auger and radiative recombination represents over 90% of the recombination at open-circuit. This dominance also holds at the maximum power point, giving pseudo-fill factors of 86%. We demonstrate the potential of thin silicon devices to reach high voltages, and bandgap-voltage offsets in line with the best reported for direct bandgap materials such as gallium indium phosphide and gallium arsenide.",

author = "Andr{\'e} Augusto and Stanislau Herasimenka and Richard King and Stuart Bowden and Christiana Honsberg",

note = "Funding Information: This material was based on work supported in part by the National Science Foundation (NSF) and the Department of Energy (DOE) under NSF CA No. EEC-1041895. We also acknowledge DOD under Grant No. DODRIF13-OEPP01-P-0020. Publisher Copyright: {\textcopyright} 2017 Author(s).",

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doi = "10.1063/1.4984071",

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AU - Augusto, André

AU - Herasimenka, Stanislau

AU - King, Richard

AU - Bowden, Stuart

AU - Honsberg, Christiana

N1 - Funding Information: This material was based on work supported in part by the National Science Foundation (NSF) and the Department of Energy (DOE) under NSF CA No. EEC-1041895. We also acknowledge DOD under Grant No. DODRIF13-OEPP01-P-0020. Publisher Copyright: © 2017 Author(s).

PY - 2017/5/28

Y1 - 2017/5/28

N2 - The mathematical dependence of bandgap-voltage offset on Auger and radiative recombination is derived. To study the recombination near the intrinsic limit, we manufacture thin silicon heterojunction test structures designed to minimize surface recombination, and to measure voltages and effective lifetimes near the Auger and radiative limit. Open-circuit voltages over 760 mV were measured on 50-μm-thick structures, leading to bandgap-voltage offsets at open-circuit down to 0.35 V. The Auger and radiative recombination represents over 90% of the recombination at open-circuit. This dominance also holds at the maximum power point, giving pseudo-fill factors of 86%. We demonstrate the potential of thin silicon devices to reach high voltages, and bandgap-voltage offsets in line with the best reported for direct bandgap materials such as gallium indium phosphide and gallium arsenide.

AB - The mathematical dependence of bandgap-voltage offset on Auger and radiative recombination is derived. To study the recombination near the intrinsic limit, we manufacture thin silicon heterojunction test structures designed to minimize surface recombination, and to measure voltages and effective lifetimes near the Auger and radiative limit. Open-circuit voltages over 760 mV were measured on 50-μm-thick structures, leading to bandgap-voltage offsets at open-circuit down to 0.35 V. The Auger and radiative recombination represents over 90% of the recombination at open-circuit. This dominance also holds at the maximum power point, giving pseudo-fill factors of 86%. We demonstrate the potential of thin silicon devices to reach high voltages, and bandgap-voltage offsets in line with the best reported for direct bandgap materials such as gallium indium phosphide and gallium arsenide.

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Analysis of the recombination mechanisms of a silicon solar cell with low bandgap-voltage offset

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