Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors

Zachary C. Holman; Miha Filipič; Benjamin Lipovšek; Stefaan De Wolf; Franc Smole; Marko Topič; Christophe Ballif

doi:10.1016/j.solmat.2013.06.024

Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors

Zachary C. Holman, Miha Filipič, Benjamin Lipovšek, Stefaan De Wolf, Franc Smole, Marko Topič, Christophe Ballif

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

74 Scopus citations

Abstract

The rear side of a silicon solar cell is often designed to minimize surface recombination, series resistance, and cost, but not necessarily parasitic absorption. We present a comprehensive study of parasitic absorption in the metal layer of solar cells with dielectric/metal rear reflectors. The sub-bandgap reflectance of a solar cell or test structure is proposed as an experimentally accessible probe of parasitic absorption, and it is correlated with short-circuit current density. The influence of surface texture, dielectric refractive index and thickness, and metal refractive index on sub-bandgap reflectance - and thus current - is then both calculated and measured. From the results, we formulate design rules that promote optimum infrared response in a wide variety of silicon solar cells.

Original language	English (US)
Pages (from-to)	426-430
Number of pages	5
Journal	Solar Energy Materials and Solar Cells
Volume	120
Issue number	PART A
DOIs	https://doi.org/10.1016/j.solmat.2013.06.024
State	Published - 2014
Externally published	Yes

Keywords

Light trapping
PERL
Parasitic absorption
Rear reflector
Silicon
Solar cell

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Renewable Energy, Sustainability and the Environment
Surfaces, Coatings and Films

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10.1016/j.solmat.2013.06.024

Cite this

Holman, Z. C., Filipič, M., Lipovšek, B., De Wolf, S., Smole, F., Topič, M., & Ballif, C. (2014). Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors. Solar Energy Materials and Solar Cells, 120(PART A), 426-430. https://doi.org/10.1016/j.solmat.2013.06.024

Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors. / Holman, Zachary C.; Filipič, Miha; Lipovšek, Benjamin et al.
In: Solar Energy Materials and Solar Cells, Vol. 120, No. PART A, 2014, p. 426-430.

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

Holman, ZC, Filipič, M, Lipovšek, B, De Wolf, S, Smole, F, Topič, M & Ballif, C 2014, 'Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors', Solar Energy Materials and Solar Cells, vol. 120, no. PART A, pp. 426-430. https://doi.org/10.1016/j.solmat.2013.06.024

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title = "Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors",

abstract = "The rear side of a silicon solar cell is often designed to minimize surface recombination, series resistance, and cost, but not necessarily parasitic absorption. We present a comprehensive study of parasitic absorption in the metal layer of solar cells with dielectric/metal rear reflectors. The sub-bandgap reflectance of a solar cell or test structure is proposed as an experimentally accessible probe of parasitic absorption, and it is correlated with short-circuit current density. The influence of surface texture, dielectric refractive index and thickness, and metal refractive index on sub-bandgap reflectance - and thus current - is then both calculated and measured. From the results, we formulate design rules that promote optimum infrared response in a wide variety of silicon solar cells.",

keywords = "Light trapping, PERL, Parasitic absorption, Rear reflector, Silicon, Solar cell",

author = "Holman, {Zachary C.} and Miha Filipi{\v c} and Benjamin Lipov{\v s}ek and {De Wolf}, Stefaan and Franc Smole and Marko Topi{\v c} and Christophe Ballif",

note = "Funding Information: Funding for this work was provided by the European Union Seventh Framework Programme ( FP7/2007–2013 ) Collaborative Project (CP) “20plμs” ( 256695 ), Axpo Naturstrom Fonds, the Swiss CTI ( 9908 PFNMM-NM ), the Slovenian Research Agency ( P2–0197 ), and the Slovene Human Resources and Scholarship Fund.",

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doi = "10.1016/j.solmat.2013.06.024",

language = "English (US)",

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T2 - Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors

AU - Holman, Zachary C.

AU - Filipič, Miha

AU - Lipovšek, Benjamin

AU - De Wolf, Stefaan

AU - Smole, Franc

AU - Topič, Marko

AU - Ballif, Christophe

N1 - Funding Information: Funding for this work was provided by the European Union Seventh Framework Programme ( FP7/2007–2013 ) Collaborative Project (CP) “20plμs” ( 256695 ), Axpo Naturstrom Fonds, the Swiss CTI ( 9908 PFNMM-NM ), the Slovenian Research Agency ( P2–0197 ), and the Slovene Human Resources and Scholarship Fund.

PY - 2014

Y1 - 2014

N2 - The rear side of a silicon solar cell is often designed to minimize surface recombination, series resistance, and cost, but not necessarily parasitic absorption. We present a comprehensive study of parasitic absorption in the metal layer of solar cells with dielectric/metal rear reflectors. The sub-bandgap reflectance of a solar cell or test structure is proposed as an experimentally accessible probe of parasitic absorption, and it is correlated with short-circuit current density. The influence of surface texture, dielectric refractive index and thickness, and metal refractive index on sub-bandgap reflectance - and thus current - is then both calculated and measured. From the results, we formulate design rules that promote optimum infrared response in a wide variety of silicon solar cells.

AB - The rear side of a silicon solar cell is often designed to minimize surface recombination, series resistance, and cost, but not necessarily parasitic absorption. We present a comprehensive study of parasitic absorption in the metal layer of solar cells with dielectric/metal rear reflectors. The sub-bandgap reflectance of a solar cell or test structure is proposed as an experimentally accessible probe of parasitic absorption, and it is correlated with short-circuit current density. The influence of surface texture, dielectric refractive index and thickness, and metal refractive index on sub-bandgap reflectance - and thus current - is then both calculated and measured. From the results, we formulate design rules that promote optimum infrared response in a wide variety of silicon solar cells.

KW - Light trapping

KW - PERL

KW - Parasitic absorption

KW - Rear reflector

KW - Silicon

KW - Solar cell

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SN - 0927-0248

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EP - 430

JO - Solar Energy Materials and Solar Cells

JF - Solar Energy Materials and Solar Cells

IS - PART A

ER -

Parasitic absorption in the rear reflector of a silicon solar cell: Simulation and measurement of the sub-bandgap reflectance for common dielectric/metal reflectors

Abstract

Keywords

ASJC Scopus subject areas

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