Carrier population control and surface passivation in solar cells

Andres Cuevas; Yimao Wan; Di Yan; Christian Samundsett; Thomas Allen; Xinyu Zhang; Jie Cui; James Bullock

doi:10.1016/j.solmat.2018.04.026

Carrier population control and surface passivation in solar cells

Andres Cuevas^*, Yimao Wan, Di Yan, Christian Samundsett, Thomas Allen, Xinyu Zhang, Jie Cui, James Bullock

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

129 Citations (Scopus)

Abstract

Controlling the concentration of charge carriers near the surface is essential for solar cells. It permits to form regions with selective conductivity for either electrons or holes and it also helps to reduce the rate at which they recombine. Chemical passivation of the surfaces is equally important, and it can be combined with population control to implement carrier-selective, passivating contacts for solar cells. This paper discusses different approaches to suppress surface recombination and to manipulate the concentration of carriers by means of doping, work function and charge. It also describes some of the many surface-passivating contacts that are being developed for silicon solar cells, restricted to experiments performed by the authors.

Original language	English
Pages (from-to)	38-47
Number of pages	10
Journal	Solar Energy Materials and Solar Cells
Volume	184
DOIs	https://doi.org/10.1016/j.solmat.2018.04.026
Publication status	Published - Sept 2018

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10.1016/j.solmat.2018.04.026

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title = "Carrier population control and surface passivation in solar cells",

abstract = "Controlling the concentration of charge carriers near the surface is essential for solar cells. It permits to form regions with selective conductivity for either electrons or holes and it also helps to reduce the rate at which they recombine. Chemical passivation of the surfaces is equally important, and it can be combined with population control to implement carrier-selective, passivating contacts for solar cells. This paper discusses different approaches to suppress surface recombination and to manipulate the concentration of carriers by means of doping, work function and charge. It also describes some of the many surface-passivating contacts that are being developed for silicon solar cells, restricted to experiments performed by the authors.",

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AU - Cuevas, Andres

AU - Wan, Yimao

AU - Yan, Di

AU - Samundsett, Christian

AU - Allen, Thomas

AU - Zhang, Xinyu

AU - Cui, Jie

AU - Bullock, James

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N2 - Controlling the concentration of charge carriers near the surface is essential for solar cells. It permits to form regions with selective conductivity for either electrons or holes and it also helps to reduce the rate at which they recombine. Chemical passivation of the surfaces is equally important, and it can be combined with population control to implement carrier-selective, passivating contacts for solar cells. This paper discusses different approaches to suppress surface recombination and to manipulate the concentration of carriers by means of doping, work function and charge. It also describes some of the many surface-passivating contacts that are being developed for silicon solar cells, restricted to experiments performed by the authors.

AB - Controlling the concentration of charge carriers near the surface is essential for solar cells. It permits to form regions with selective conductivity for either electrons or holes and it also helps to reduce the rate at which they recombine. Chemical passivation of the surfaces is equally important, and it can be combined with population control to implement carrier-selective, passivating contacts for solar cells. This paper discusses different approaches to suppress surface recombination and to manipulate the concentration of carriers by means of doping, work function and charge. It also describes some of the many surface-passivating contacts that are being developed for silicon solar cells, restricted to experiments performed by the authors.

KW - Carrier-selective contacts

KW - Silicon solar cells

KW - Surface passivation

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VL - 184

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JO - Solar Energy Materials and Solar Cells

JF - Solar Energy Materials and Solar Cells

ER -

Carrier population control and surface passivation in solar cells

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