2020
DOI: 10.1021/acsaem.9b01781
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Benchmarked Photoelectrochemical Water Splitting by Nickel-Doped n-Type Cuprous Oxide

Abstract: Herein, Ni is for the first time put forward as a promising dopant to promote the photoelectrochemical property of cuprous oxide (Cu 2 O) with particularly n-type conduction. An electrochemical route is utilized to deposit Ni:Cu 2 O on the indium tin oxide (ITO) coated glass as a dense thin film with tree-like morphology, as revealed through scanning electron microscopy. Particularly, the incorporation of Ni that is verified via X-ray diffractometry leads to a compressive stress compensating well the tensile s… Show more

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Cited by 22 publications
(18 citation statements)
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“…Among them, the highest photocurrent density amounting to 2 mA cm –2 is seen in the LSV curve of Cu 2 O precipitated on ITO subjected to the electrochemically forced reduction at −1.5 V Ag/AgCl and, more importantly, at an applied potential of 0.05 V Ag/AgCl , which is far negative than that of the Cu 2 O counterpart on pristine ITO by 200 mV. Most significantly, this in turn renders ABPE of Cu 2 O deposited on ITO subjected to the electrochemically forced reduction at −1.5 V Ag/AgCl reach 1.1%, which is among the highest performance reported to date for a variety of state-of-the-art metal oxide-based photoanodes in the literature , (Figure a and Table S1). The best performance of this photoanode unambiguously highlights the important role of the external bias of −1.5 V Ag/AgCl applied to ITO, which decreases the work function of ITO via the oxygen vacancy introduced to ITO for compensating the charge caused by its electrochemically forced reduction into metallic indium (Figures c, and S1).…”
Section: Resultsmentioning
confidence: 97%
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“…Among them, the highest photocurrent density amounting to 2 mA cm –2 is seen in the LSV curve of Cu 2 O precipitated on ITO subjected to the electrochemically forced reduction at −1.5 V Ag/AgCl and, more importantly, at an applied potential of 0.05 V Ag/AgCl , which is far negative than that of the Cu 2 O counterpart on pristine ITO by 200 mV. Most significantly, this in turn renders ABPE of Cu 2 O deposited on ITO subjected to the electrochemically forced reduction at −1.5 V Ag/AgCl reach 1.1%, which is among the highest performance reported to date for a variety of state-of-the-art metal oxide-based photoanodes in the literature , (Figure a and Table S1). The best performance of this photoanode unambiguously highlights the important role of the external bias of −1.5 V Ag/AgCl applied to ITO, which decreases the work function of ITO via the oxygen vacancy introduced to ITO for compensating the charge caused by its electrochemically forced reduction into metallic indium (Figures c, and S1).…”
Section: Resultsmentioning
confidence: 97%
“…The broad band alongside at B.E. of ∼945 eV is attributed to the characteristic shake-up satellite of CuO. , CuO has been reported to originate most likely from the oxidation of Cu 2 O upon the exposure to air, which was nevertheless limited at the surface to in turn account for the relative abundance of CuO far below that of Cu 2 O. , In addition, Cu 2 O crystals electrodeposited on pristine ITO and ITO subjected to the electrochemically forced reduction are all featured with an optical band gap E g ∼ 2.0 eV determined from the Tauc plots in Figure c.…”
Section: Resultsmentioning
confidence: 99%
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