Facile, sustainable and unassisted plain water oxidation on Au/Ce0.9Ti0.1O2 nanorods in direct sunlight

IF 1.7 4区 化学 Q3 Chemistry Journal of Chemical Sciences Pub Date : 2022-04-30 DOI:10.1007/s12039-022-02055-z
Anjani Dubey, Abhaya Kumar Mishra, Sanjay Singh Negi, Chinnakonda S Gopinath
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引用次数: 4

Abstract

Impressive rate of solar water oxidation to molecular oxygen (O2) has been demonstrated on nanorods (NRs) of Ce0.9Ti0.1O2 (CT-NR) and Au-deposited CT-NR (Au-CT-NR) photocatalysts with a sacrificial agent (Fe3+) and in plain water in one sun condition, direct sunlight and with λ ≥ 455 nm. Probably the highest O2 yield of 11 mmol/h.g was observed with Au-CT-NR thin film in plain water in direct sunlight, with no sacrificial agent or applied potential. Photoelectrochemical measurements demonstrate a marked reduction in oxidation onset potential of Au-CT-NR by 150 mV with stable photocurrent (0.75 mA/cm2), compared to CT-NR (0.23 mA/cm2), indicating the operative of plasmon-induced resonant energy transfer (PIRET) process. Effective electron quenching by nanogold and hence low recombination in the depletion region is a critical step for the observation of a high rate of oxygen evolution. In addition to this, a predominant change in the nature of the valence band from O-2p dominated on CeO2 to Ce-4f dominated with CT-NR (due to Ti4+ introduction in CeO2), the efficient light absorption of photocatalysts in thin-film form, functional and effective PIRET process, and facile EF alignment, enhances the oxygen evolution with Au-CT-NR in direct sunlight and make it highly sustainable. A possible mechanism of water oxidation is proposed from the observed experimental findings.

Graphical abstract

Extraordinary water oxidation capacity to O2 in sunlight was achieved with a thin-film form of Au-CeTiO2-NR by efficient light absorption followed by effective electron trapping in gold. This minimizes charge recombination and hence minority carriers were efficiently utilized. Reduction in overpotential, Fermi level equilibration and PIRET process due to nano-gold significantly improve the water oxidation capacity in a sustainable manner.

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Au/Ce0.9Ti0.1O2纳米棒在阳光直射下的简单、可持续和无辅助的水氧化
以Ce0.9Ti0.1O2 (CT-NR)和au -沉积CT-NR (Au-CT-NR)为光催化剂,采用牺牲剂(Fe3+),在光照直射和λ≥455 nm条件下,在平水条件下,在Ce0.9Ti0.1O2 (CT-NR)纳米棒(nr)上,证明了太阳水氧化成分子氧(O2)的惊人速率。O2产率最高可达11 mmol/h。用Au-CT-NR薄膜在阳光直射下的清水中观察g,无牺牲剂或施加电位。光电化学测量表明,与CT-NR (0.23 mA/cm2)相比,在稳定的光电流(0.75 mA/cm2)下,Au-CT-NR的氧化电位显著降低了150 mV,表明等离子体诱导的共振能量转移(PIRET)过程的作用。纳米金的有效电子猝灭和耗尽区的低复合是观察高析氧速率的关键步骤。此外,由于CeO2中引入了Ti4+,价带的性质从CeO2上的O-2p为主转变为CT-NR上的Ce-4f为主,光催化剂薄膜形式的高效光吸收,功能有效的PIRET过程,以及易于的EF排列,增强了Au-CT-NR在阳光直射下的析氧,使其具有很高的可持续性。根据观察到的实验结果,提出了一种可能的水氧化机理。在阳光下,Au-CeTiO2-NR薄膜通过有效的光吸收和金中的有效电子捕获,实现了水对O2的特殊氧化能力。这使电荷重组最小化,从而有效地利用了少数载流子。由于纳米金的存在,过电位降低、费米能级平衡和PIRET过程显著提高了水的氧化能力。
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来源期刊
Journal of Chemical Sciences
Journal of Chemical Sciences Chemistry-General Chemistry
CiteScore
2.90
自引率
5.90%
发文量
107
审稿时长
12 months
期刊介绍: Journal of Chemical Sciences is a monthly journal published by the Indian Academy of Sciences. It formed part of the original Proceedings of the Indian Academy of Sciences – Part A, started by the Nobel Laureate Prof C V Raman in 1934, that was split in 1978 into three separate journals. It was renamed as Journal of Chemical Sciences in 2004. The journal publishes original research articles and rapid communications, covering all areas of chemical sciences. A significant feature of the journal is its special issues, brought out from time to time, devoted to conference symposia/proceedings in frontier areas of the subject, held not only in India but also in other countries.
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