Journal
SOLAR ENERGY MATERIALS AND SOLAR CELLS
Volume 186, Issue -, Pages 9-13Publisher
ELSEVIER
DOI: 10.1016/j.solmat.2018.06.019
Keywords
Poly-silicon; Carrier selective passivating contact; Light in-coupling; IBC c-Si solar cells
Funding
- Dutch Ministry of Economic Affairs (TKI Solar Energy projects)
- European Union's Horizon2020 Programme for research, technological development and demonstration [727523]
- H2020 Societal Challenges Programme [727523] Funding Source: H2020 Societal Challenges Programme
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In this work, we present the application of poly-Si carrier-selective passivating contacts (CSPCs) as both polarities in interdigitated back-contacted (IBC) solar cell architectures. We compared two approaches to form a gap between the back-surface field (BSF) and emitter fingers. It is proved that the gaps prepared by both approaches are efficient in preventing carriers' recombination. To minimize the reflection losses, we developed a novel modulated surface texturing (MST) structure as anti-reflection coating (ARC). It is obtained by superposing a nano-textured SiO2 layer on the conventional micro-textured pyramids, which are passivated with a-Si:H / SiNx:H layers. This approach decouples the light harvesting from the Si surface passivation, which potentially results in the highest possible optical and electrical performances of the solar cells. The reflectance (R) of the MST-ARC is very close to that of the high-aspect ratio nano-structured silicon (black-Silicon), achieving R < 1% between 450 and 1000 nm. The J(0) of MST-ARC passivated Si surface (6.3 fA/cm(2)) is the same as that of standard a-Si:H/SiNx:H layers passivated pyramidally-textured Si surface. By applying this novel MST-ARC in our IBC solar cell, the highest J(SC) observed in a device is 42.2 mA/cm(2) with a V-OC as high as 701 mV. A spectral response enhancement in case of the MST-ARC cell is observed over the whole wavelength range with respect to the cell with standard SiNx:H ARC. The highest efficiency achieved in this work is 23.0%, with the potential to reach 24.0% in short term by using more conductive metal fingers.
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