D. Kania scite author profile

Aluminum oxide layers can provide excellent passivation for lowly and highly doped p-type silicon surfaces. Fixed negative charges induce an accumulation layer at the p-type silicon interface, resulting in very effective field-effect passivation. This paper presents highly negatively charged (Q(ox)=-2.1 X 10(12) cm(-2)) aluminum oxide layers produced using an inline plasma-enhanced chemical vapor deposition system, leading to very low effective recombination velocities (similar to 10 cm s(-1)) on low-resistivity p-type substrates. A minimum static deposition rate (100 nm min(-1)) at least one order of magnitude higher than atomic layer deposition was achieved on a large carrier surfaces (similar to 1 m(2)) without significantly reducing the resultant passivation quality

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Wavelengths and Energy Levels for the Zn I Isoelectronic Sequence Sn20+ Through U62+

Brown

Seely

Kania

et al. 1994

Atomic Data and Nuclear Data Tables

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High-Efficiency c-Si Solar Cells Passivated With ALD and PECVD Aluminum Oxide

Saint‐Cast

Benick

Kania

et al. 2010

IEEE Electron Device Lett.

140

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High-temperature stability of c-Si surface passivation by thick PECVD Al2O3 with and without hydrogenated capping layers

Saint‐Cast

Kania

Heller

et al. 2012

Applied Surface Science

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Fully Ion Implanted and Coactivated Industrial n-Type Cells With 20.5% Efficiency

Böscke

Kania

Schöllhorn

et al. 2014

IEEE J. Photovoltaics

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D. Kania

Very low surface recombination velocity on p-type c-Si by high-rate plasma-deposited aluminum oxide

Wavelengths and Energy Levels for the Zn I Isoelectronic Sequence Sn20+ Through U62+

High-Efficiency c-Si Solar Cells Passivated With ALD and PECVD Aluminum Oxide

High-temperature stability of c-Si surface passivation by thick PECVD Al2O3 with and without hydrogenated capping layers

Fully Ion Implanted and Coactivated Industrial n-Type Cells With 20.5% Efficiency

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