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Broadband Antireflection Mie Scatterers Revisited - a Solar Cell and Module Analysis

: Stevens, L.; Tucher, N.; Höhn, O.; Hauser, H.; Müller, C.; Bläsi, B.

Volltext urn:nbn:de:0011-n-5486568 (2.2 MByte PDF)
MD5 Fingerprint: 921729af6c593be218de22f31f91cc95
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Erstellt am: 17.8.2019

Optics Express 27 (2019), Nr.8, S.A524-A535
ISSN: 1094-4087
Bundesministerium fur Wirtschaft und Energie BMWi (Deutschland)
0324151A; SOLGEL-PV
Zeitschriftenaufsatz, Elektronische Publikation
Fraunhofer ISE ()
Mikrostrukturierte Oberflächen; Photovoltaik; Silicium-Photovoltaik; Photovoltaik; Neuartige Photovoltaik-Technologien; Oberflächen: Konditionierung; Passivierung; Lichteinfang; Photonenmanagement

Reflectance, reduction, and light trapping enhancement are essential to maximize the absorption of silicon solar cells. The industrial state of the art method to improve the solar cell optics is wet chemical texturization of the front surface in combination with the deposition of antireflection coatings. This work analyzes an alternative route, namely a TiO2 pillar structure on the front side of a planar silicon solar cell encapsulated in ethylene vinyl acetate (EVA) and glass. It focuses on parameter variations of the structured TiO2 layer while taking the module encapsulation into account. It is shown that internal reflections at the front interface of the module play a crucial role for the structure design. This leads to optimized structures working in a different optical regime. While state of the art structures optimized for a half infinite encapsulation act as effective media, structures optimized for the full module show an improved performance by making use of diffractive effects. It could be shown that weighted reflectance of 4.7% can be reached for a solar module with TiO2 pillar structure on top of the silicon surface compared to 5.5% for a two-layer ARC with a TiO2 bottom layer and 2.3% for an isotexture, which is the state of the art structure for multicrystalline silicon cells.