Growing Ultrathin Cu2O Films on Highly Crystalline Cu(111): A Closer Inspection from Microscopy and Theory

Cu2O has been investigated for decades to understand the complex nature of oxidation and to utilize its high catalytic activity and intrinsic p-type character. However, the structures and intrinsic defects of Cu2O­(111) surfaces have not been fully explored at the atomistic level, which is required...

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Published in:Journal of physical chemistry. C 2019-05, Vol.123 (20), p.12716-12721
Main Authors: Ly, Trinh Thi, Lee, Taehun, Kim, Sanghwa, Lee, Yun-Jae, Duvjir, Ganbat, Jang, Kyuha, Palotás, Krisztián, Jeong, Se-Young, Soon, Aloysius, Kim, Jungdae
Format: Article
Language:English
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Summary:Cu2O has been investigated for decades to understand the complex nature of oxidation and to utilize its high catalytic activity and intrinsic p-type character. However, the structures and intrinsic defects of Cu2O­(111) surfaces have not been fully explored at the atomistic level, which is required to clarify some issues such as termination of Cu2O­(111) surfaces. Here, our combined scanning tunneling microscopy (STM) and density functional theory (DFT) studies show that Cu2O­(111) has a stoichiometric surface where the coordinately unsaturated Cu atoms appear with a hexagonal lattice. DFT simulations reflecting the orbital contributions of the STM tip present a good agreement with STM topography, unveiling the fine structures of Cu2O­(111) surfaces that arise from coordinately saturated Cu atoms. Besides the possibility of kinetically formed oxygen vacancies reported in a previous work, two intrinsic defects identified in this work as a Cu vacancy (VCu) and Cu adatoms commonly exist on Cu2O­(111) surfaces. Intriguingly, direct experimental evidence indicates that VCu plays the role of a hole provider in Cu2O. The topographic contrast of VCu is inverted by reversing the polarity of the sample bias, and VCu also exhibits strongly enhanced dI/dV spectrum at negative bias. These results imply that VCu is negatively charged due to its acceptor character. We expect that our observations will provide important information to establish an in-depth understanding of the fundamental properties of Cu2O.
ISSN:1932-7447
1932-7455
DOI:10.1021/acs.jpcc.9b00255