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Elucidating the origin of external quantum efficiency losses in cuprous oxide solar cells through defect analysis

descriptionPublicationkeyboard_double_arrow_right Article , Journal 01 Jun 2020Embargo end date: 28 Feb 2020 Norway, United Kingdom Publisher:Elsevier BVJournal:Solar Energy Materials and Solar Cells, volume 209, page 110,418 (issn: 0927-0248,

Authors: Gan, J; Hoye, R; Ievskaya, Y; Vines, L; Marin, A; MacManus-Driscoll, J; Monakhov, E;

doi: 10.1016/j.solmat.2020.110418 , 10.17863/cam.49912

handle: 10852/83109 , 10044/1/77005

Elucidating the origin of external quantum efficiency losses in cuprous oxide solar cells through defect analysis

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Abstract

Heterojunction Cu2O solar cells are an important class of Earth-abundant photovoltaics that can be synthesized by a variety of techniques, including electrochemical deposition (ECD) and thermal oxidation (TO). The latter gives the most efficient solar cells of up to 8.1% reported in the literature, but is limited by low external quantum efficiencies (EQE) in the long wavelength range (490–600 nm). By contrast, ECD Cu2O gives higher short wavelength EQEs of up to 90%. We elucidate the cause of this difference by characterizing and comparing ECD and TO films using impedance spectroscopy and fitting with a lumped circuit model to determine the trap density, followed by simulations. The data indicates that TO Cu2O has a higher density of interface defects, located approximately 0.5 eV above the valence band maximum (NV), and lower bulk defect density thus explaining the lower short wavelength EQEs and higher long wavelength EQEs. This work shows that a route to further efficiency increases of TO Cu2O is to reduce the density of interface defect states.

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Norway, United Kingdom

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Keywords

02 Physical Sciences, Energy, 34 Chemical Sciences, 540, 530, 09 Engineering, 4016 Materials Engineering, 03 Chemical Sciences, 51 Physical Sciences, 40 Engineering

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