Optimized spatial correlations for broadband light trapping nanopatterns in high efficiency ultrathin film a-Si:H solar cells

Vivian E. Ferry; Marc A. Verschuuren; M. Claire Van Lare; Ruud E I Schropp; Harry A. Atwater; Albert Polman

doi:10.1021/nl202226r

Optimized spatial correlations for broadband light trapping nanopatterns in high efficiency ultrathin film a-Si:H solar cells

Vivian E. Ferry
, Marc A. Verschuuren
, M. Claire Van Lare
, Ruud E I Schropp
, Harry A. Atwater
, Albert Polman

Chemical Engineering and Materials Science

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

364 Scopus citations

Abstract

Nanophotonic structures have attracted attention for light trapping in solar cells with the potential to manage and direct light absorption on the nanoscale. While both randomly textured and nanophotonic structures have been investigated, the relationship between photocurrent and the spatial correlations of random or designed surfaces has been unclear. Here we systematically design pseudorandom arrays of nanostructures based on their power spectral density, and correlate the spatial frequencies with measured and simulated photocurrent. The integrated cell design consists of a patterned plasmonic back reflector and a nanostructured semiconductor top interface, which gives broadband and isotropic photocurrent enhancement.

Original language	English (US)
Pages (from-to)	4239-4245
Number of pages	7
Journal	Nano letters
Volume	11
Issue number	10
DOIs	https://doi.org/10.1021/nl202226r
State	Published - Oct 12 2011

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

Thin film solar cells
light trapping
nanoimprint lithography
photovoltaics
silicon
surface plasmon polariton

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10.1021/nl202226r

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abstract = "Nanophotonic structures have attracted attention for light trapping in solar cells with the potential to manage and direct light absorption on the nanoscale. While both randomly textured and nanophotonic structures have been investigated, the relationship between photocurrent and the spatial correlations of random or designed surfaces has been unclear. Here we systematically design pseudorandom arrays of nanostructures based on their power spectral density, and correlate the spatial frequencies with measured and simulated photocurrent. The integrated cell design consists of a patterned plasmonic back reflector and a nanostructured semiconductor top interface, which gives broadband and isotropic photocurrent enhancement.",

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T1 - Optimized spatial correlations for broadband light trapping nanopatterns in high efficiency ultrathin film a-Si:H solar cells

AU - Ferry, Vivian E.

AU - Verschuuren, Marc A.

AU - Lare, M. Claire Van

AU - Schropp, Ruud E I

AU - Atwater, Harry A.

AU - Polman, Albert

PY - 2011/10/12

Y1 - 2011/10/12

N2 - Nanophotonic structures have attracted attention for light trapping in solar cells with the potential to manage and direct light absorption on the nanoscale. While both randomly textured and nanophotonic structures have been investigated, the relationship between photocurrent and the spatial correlations of random or designed surfaces has been unclear. Here we systematically design pseudorandom arrays of nanostructures based on their power spectral density, and correlate the spatial frequencies with measured and simulated photocurrent. The integrated cell design consists of a patterned plasmonic back reflector and a nanostructured semiconductor top interface, which gives broadband and isotropic photocurrent enhancement.

AB - Nanophotonic structures have attracted attention for light trapping in solar cells with the potential to manage and direct light absorption on the nanoscale. While both randomly textured and nanophotonic structures have been investigated, the relationship between photocurrent and the spatial correlations of random or designed surfaces has been unclear. Here we systematically design pseudorandom arrays of nanostructures based on their power spectral density, and correlate the spatial frequencies with measured and simulated photocurrent. The integrated cell design consists of a patterned plasmonic back reflector and a nanostructured semiconductor top interface, which gives broadband and isotropic photocurrent enhancement.

KW - Thin film solar cells

KW - light trapping

KW - nanoimprint lithography

KW - photovoltaics

KW - silicon

KW - surface plasmon polariton

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U2 - 10.1021/nl202226r

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M3 - Article

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AN - SCOPUS:80054010598

SN - 1530-6984

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JO - Nano letters

JF - Nano letters

IS - 10

ER -

Optimized spatial correlations for broadband light trapping nanopatterns in high efficiency ultrathin film a-Si:H solar cells

Abstract

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Keywords

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