Plasmonic light trapping in thin-film Si solar cells

P. Spinelli; E. Ferry; J. Van De Groep; M. Van Lare; A. Verschuuren; I. Schropp; A. Atwater; A. Polman; P. Spinelli; V. E. Ferry; J. Van De Groep; M. Van Lare; M. A. Verschuuren; R. E I Schropp; H. A. Atwater; A. Polman

doi:10.1088/2040-8978/14/2/024002

Plasmonic light trapping in thin-film Si solar cells

P. Spinelli, E. Ferry, J. Van De Groep, M. Van Lare, A. Verschuuren, I. Schropp, A. Atwater, A. Polman, P. Spinelli, V. E. Ferry, J. Van De Groep, M. Van Lare, M. A. Verschuuren, R. E I Schropp, H. A. Atwater, A. Polman

Chemical Engineering and Materials Science

Research output: Contribution to journal › Review article › peer-review

338 Scopus citations

Abstract

Plasmonic nanostructures have been recently investigated as a possible way to improve absorption of light in solar cells. The strong interaction of small metal nanostructures with light allows control over the propagation of light at the nanoscale and thus the design of ultrathin solar cells in which light is trapped in the active layer and efficiently absorbed. In this paper we review some of our recent work in the field of plasmonics for improved solar cells. We have investigated two possible ways of integrating metal nanoparticles in a solar cell. First, a layer of Ag nanoparticles that improves the standard antireflection coating used for crystalline and amorphous silicon solar cells has been designed and fabricated. Second, regular and random arrays of metal nanostructures have been designed to couple light in waveguide modes of thin semiconductor layers. Using a large-scale, relative inexpensive nano-imprint technique, we have designed a back-contact light trapping surface for a-Si:H solar cells which show enhanced efficiency over standard randomly textured cells.

Original language	English (US)
Article number	024002
Journal	Journal of Optics
Volume	14
Issue number	2
DOIs	https://doi.org/10.1088/2040-8978/14/2/024002
State	Published - Feb 2012

Keywords

light trapping
plasmonics
solar cells
thin-film

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

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Spinelli, P., Ferry, E., Van De Groep, J., Van Lare, M., Verschuuren, A., Schropp, I., Atwater, A., Polman, A., Spinelli, P., Ferry, V. E., Van De Groep, J., Van Lare, M., Verschuuren, M. A., Schropp, R. E. I., Atwater, H. A., & Polman, A. (2012). Plasmonic light trapping in thin-film Si solar cells. Journal of Optics, 14(2), Article 024002. https://doi.org/10.1088/2040-8978/14/2/024002

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abstract = "Plasmonic nanostructures have been recently investigated as a possible way to improve absorption of light in solar cells. The strong interaction of small metal nanostructures with light allows control over the propagation of light at the nanoscale and thus the design of ultrathin solar cells in which light is trapped in the active layer and efficiently absorbed. In this paper we review some of our recent work in the field of plasmonics for improved solar cells. We have investigated two possible ways of integrating metal nanoparticles in a solar cell. First, a layer of Ag nanoparticles that improves the standard antireflection coating used for crystalline and amorphous silicon solar cells has been designed and fabricated. Second, regular and random arrays of metal nanostructures have been designed to couple light in waveguide modes of thin semiconductor layers. Using a large-scale, relative inexpensive nano-imprint technique, we have designed a back-contact light trapping surface for a-Si:H solar cells which show enhanced efficiency over standard randomly textured cells.",

keywords = "light trapping, plasmonics, solar cells, thin-film",

author = "P. Spinelli and E. Ferry and {Van De Groep}, J. and {Van Lare}, M. and A. Verschuuren and I. Schropp and A. Atwater and A. Polman and P. Spinelli and Ferry, {V. E.} and {Van De Groep}, J. and {Van Lare}, M. and Verschuuren, {M. A.} and Schropp, {R. E I} and Atwater, {H. A.} and A. Polman",

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AU - Spinelli, P.

AU - Ferry, E.

AU - Van De Groep, J.

AU - Van Lare, M.

AU - Verschuuren, A.

AU - Schropp, I.

AU - Atwater, A.

AU - Polman, A.

AU - Spinelli, P.

AU - Ferry, V. E.

AU - Van De Groep, J.

AU - Van Lare, M.

AU - Verschuuren, M. A.

AU - Schropp, R. E I

AU - Atwater, H. A.

AU - Polman, A.

PY - 2012/2

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N2 - Plasmonic nanostructures have been recently investigated as a possible way to improve absorption of light in solar cells. The strong interaction of small metal nanostructures with light allows control over the propagation of light at the nanoscale and thus the design of ultrathin solar cells in which light is trapped in the active layer and efficiently absorbed. In this paper we review some of our recent work in the field of plasmonics for improved solar cells. We have investigated two possible ways of integrating metal nanoparticles in a solar cell. First, a layer of Ag nanoparticles that improves the standard antireflection coating used for crystalline and amorphous silicon solar cells has been designed and fabricated. Second, regular and random arrays of metal nanostructures have been designed to couple light in waveguide modes of thin semiconductor layers. Using a large-scale, relative inexpensive nano-imprint technique, we have designed a back-contact light trapping surface for a-Si:H solar cells which show enhanced efficiency over standard randomly textured cells.

AB - Plasmonic nanostructures have been recently investigated as a possible way to improve absorption of light in solar cells. The strong interaction of small metal nanostructures with light allows control over the propagation of light at the nanoscale and thus the design of ultrathin solar cells in which light is trapped in the active layer and efficiently absorbed. In this paper we review some of our recent work in the field of plasmonics for improved solar cells. We have investigated two possible ways of integrating metal nanoparticles in a solar cell. First, a layer of Ag nanoparticles that improves the standard antireflection coating used for crystalline and amorphous silicon solar cells has been designed and fabricated. Second, regular and random arrays of metal nanostructures have been designed to couple light in waveguide modes of thin semiconductor layers. Using a large-scale, relative inexpensive nano-imprint technique, we have designed a back-contact light trapping surface for a-Si:H solar cells which show enhanced efficiency over standard randomly textured cells.

KW - light trapping

KW - plasmonics

KW - solar cells

KW - thin-film

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ER -

Plasmonic light trapping in thin-film Si solar cells

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