Ultrathin CuO Hole-Selective Contact for Efficient GaAs Solar Cells
Date
2026
Authors
Duhan, P.
Bartholazzi, G.
Haggren, T.
Gupta, B.
Adhikari, S.
Black, L.E.
Zhang, D.
Jagadish, C.
Karuturi, S.
Tan, H.H.
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Journal article
Citation
ACS Applied Energy Materials, 2026; 9(6):3263-3271
Statement of Responsibility
Parul Duhan, Gabriel Bartholazzi, Tuomas Haggren, Bikesh Gupta, Sonachand Adhikari, Lachlan E. Black, Doudou Zhang, Chennupati Jagadish, Siva Karuturi, Hark Hoe Tan
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Abstract
GaAs heterojunction solar cells with carrier-selective contacts are emerging as a promising alternative to traditional homojunction GaAs solar cells, offering low-cost fabrication, elimination of complex semiconductor doping processes, and high efficiency potential. Despite significant progress, the performance of GaAs heterojunction solar cells remains constrained by nonradiative recombination and processing issues, particularly for devices with a hole-selective contact. In this work, using SCAPS-1D simulations of the GaAs/CuO/PEDOT:PSS structure, we show that undoped GaAs with a thickness of ∼1.5 μm, combined with a 2 nm CuO layer, maximizes Jsc, Voc, fill factor, and overall efficiency. Guided by these simulations, we experimentally show that an ultrathin (2 nm) CuO layer deposited by plasma-enhanced atomic layer deposition is an effective hole-selective contact for GaAs heterojunction solar cells. X-ray and ultraviolet photoelectron spectroscopy show favorable band alignment at the CuO/GaAs interface, with a low valence band offset (0.11 eV) and large conduction band offset (0.52 eV), confirming its electron-blocking and hole-selective behavior. The CuO layer increases Voc, Jsc, fill factor, and overall efficiency from 8.6% to 13.5%. Power loss analysis indicates that optical losses are the primary contributors, suggesting a clear approach to achieving higher efficiencies.
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© 2026 American Chemical Society