Engineering intrinsic defects in CuO NWs through laser irradiation: Oxygen vs copper vacancies

Engineering intrinsic defects in CuO NWs through laser irradiation: Oxygen vs copper vacancies

[Display omitted] •Nanosecond laser irradiation produces either copper or oxygen vacancies depending on the atmosphere during the process.•The generation of copper vacancies can be confirmed by XPS and Raman spectroscopy.•Oxygen vacancies improves the performance of CuO nanowires for glucose sensing...

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Bibliographic Details
Published in:Applied surface science 2024-01, Vol.642, p.158630, Article 158630
Main Authors: Zheng, Shuo, Duley, Walter W., Peng, Peng, Norman Zhou, Y
Format: Article
Language:eng
Subjects:
Copper vacancy
Defect engineering
Non-enzymatic glucose sensing
Oxygen vacancy
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Summary:[Display omitted] •Nanosecond laser irradiation produces either copper or oxygen vacancies depending on the atmosphere during the process.•The generation of copper vacancies can be confirmed by XPS and Raman spectroscopy.•Oxygen vacancies improves the performance of CuO nanowires for glucose sensing while copper vacancies deteriorate it. Defect engineering in CuO nanomaterials has been extensively investigated because this technology can greatly improve the performance of CuO components in a variety of applications. While many previous studies have focused on the role of oxygen vacancies, (VO), in CuO, little attention has been paid to that of copper vacancy centers, (VCu), since the presence of these defects is often difficult to quantify. As a result, the specific roles played by these different vacancy centers on the measured properties of CuO have not been studied systematically. In this article, we show that the concentration of both VO and VCu centers can be engineered in CuO NWs through nanosecond (ns) laser irradiation. The identification of these vacancies was achieved through X-ray photoelectron spectroscopy (XPS) and Raman spectroscopy. Absorption spectra and diffuse reflectance spectra of laser-processed samples show that increasing the concentration of VO centers enhances the optical absorption of CuO in the visible region. Data obtained from Mott-Schottky and Nyquist plots, together with measured I-V characteristics, show that laser-induced VCu centers can enhance the carrier concentration in CuO NWs. These data, in addition to O 1s XPS spectra on laser-processed and unprocessed samples as well as cyclic voltammetry, also indicate that laser irradiation can significantly enhance surface adsorption for applications in photo-electrochemistry and electrochemistry. To demonstrate the efficacy of this laser irradiation technique for potential electrochemistry applications, the role of laser-induced VCu and VO defect centers in CuO NWs on the non-enzymatic sensing of glucose has also been investigated. We find that the introduction of VO centers in CuO NWs enhances the current response for glucose sensing while the presence of VCu centers inhibits this response.
ISSN:0169-4332
1873-5584