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24. A p–n Junction by Coupling Amine-Enriched Brookite–TiO 2 Nanorods with Cu x S Nanoparticles for Improved Photocatalytic CO 2 Reduction.

Author

Chen, Zhangjing, Zhu, Xueteng, Xiong, Jinyan, Wen, Zhipan, and Cheng, Gang

Subjects
CARBON dioxide, COPPER, NANORODS, PHOTOREDUCTION, NANOPARTICLES, METHANATION
Abstract

Photocatalytic CO2 reduction is a promising technology for reaching the aim of "carbon peaking and carbon neutrality", and it is crucial to design efficient photocatalysts with a rational surface and interface tailoring. Considering that amine modification on the surface of the photocatalyst could offer a favorable impact on the adsorption and activation of CO2, in this work, amine-modified brookite TiO2 nanorods (NH2-B-TiO2) coupled with CuxS (NH2-B-TiO2-CuxS) were effectively fabricated via a facile refluxing method. The formation of a p–n junction at the interface between the NH2-B-TiO2 and the CuxS could facilitate the separation and transfer of photogenerated carriers. Consequently, under light irradiation for 4 h, when the CuxS content is 16%, the maximum performance for conversion of CO2 to CH4 reaches at a rate of 3.34 μmol g−1 h−1 in the NH2-B-TiO2-CuxS composite, which is approximately 4 times greater than that of pure NH2-B-TiO2. It is hoped that this work could deliver an approach to construct an amine-enriched p–n junction for efficient CO2 photoreduction. [ABSTRACT FROM AUTHOR]

Published
2023
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36. Integrated Ni(OH)2-TiO2-Cu2O Hybrids with a Synergic Impact of the p–n Heterojunction/Cocatalyst for Enhanced Photocatalytic Hydrogen Production

Author

Wang, Chunyan, Xiong, Jinyan, Wen, Zhipan, and Cheng, Gang

Abstract

Designing a hybrid photocatalyst with multichannel charge separation could address the issue of rapid recombination of photo-induced electron–hole pairs from a single semiconductor and assist photocatalytic hydrogen evolution. In this work, the Ni(OH)2-TiO2-Cu2O ternary hybrid has been successfully prepared with a combination of hydrothermal-calcination-chemical reduction methods. Particularly, Ni(OH)2species and Cu2O nanoparticles are anchored on a TiO2nanoflake assembly. Upon light illumination, photocatalytically splitting water to hydrogen is achieved by the as-synthesized ternary hybrids. Among them, the 0.83% Ni(OH)2-TiO2–4.5% Cu2O hybrid exhibits the highest photocatalytic performance. Particularly, the hydrogen generation rate (8384.84 μmol g–1h –1) of 0.83% Ni(OH)2-TiO2–4.5% Cu2O is 3.5 times higher than that of pristine TiO2(2369.94 μmol g–1h –1). It is also superior to the binary 0.83% Ni(OH)2-TiO2and TiO2–4.5% Cu2O samples. It is demonstrated that the formed p–n junction in the interface of TiO2and Cu2O as well as the cocatalytic effect of Ni(OH)2species could offer multichannels for efficient charge transfer, contributing to the improved photocatalytic hydrogen production.

Published
2023
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37. New insights on nanostructure of ordered mesoporous Fe[sbnd]Mn bimetal oxides (OMFMs) by a novel inverse micelle method and their superior arsenic sequestration performance: Effect of calcination temperature and role of Fe/Mn oxides.

Author

Lu, Jun, Wen, Zhipan, Zhang, Yalei, Cheng, Gang, Xu, Rui, Gong, Xiaohu, Wang, Xin, and Chen, Rong

Abstract

A series of ordered mesoporous Fe Mn bimetal oxides (OMFMs) were fabricated by using a novel inverse micelle method, and the texture, nanostructure and interface chemistry properties of OMFMs were closely correlated to the calcination temperature. Due to the amorphous regular inner-connected nanostructure and bimetallic synergistic effect, the obtained OMFMs exhibited superior arsenic sequestration performance than pure mesoporous Fe oxides (PMF) and Mn oxides (PMM). The optimum ratio of Fe/Mn and calcination temperature for arsenic removal was 3/1 and 350 °C (OMFM-3), and the maximum As(III) and As(V) adsorption capacities of OMFM-3 were 174.59 and 134.58 mg/g, respectively. Solution pH value negligibly affected the uptake of arsenic (ranged from 3.0 to 7.0), while SiO 3 2−/PO 4 3− ions and humic acid (HA) displayed significant inhibitory effect on arsenic removal by OMFM-3. According to the mechanism of arsenic removal, which simultaneously analyzed the arsenic redox transformation in aqueous phase and on solid phase interface, it was concluded that manganese oxides in OMFM-3 mainly played the role as a remarkable As(III) oxidant in water, whereas iron oxides dominantly acted as an excellent arsenic species adsorbent. Finally, the prominent arsenic sequestration behavior and performance in surface water suggested that OMFM-3 could be a promising and hopeful candidate for arsenic-contaminated (especially As(III)) surface water and groundwater remediation and treatment. Unlabelled Image • A series of OMFMs were successfully fabricated via a novel inverse micelle method. • Calcination temperature affected the nanostructure and surface chemistry of OMFMs. • SiO 3 2−/PO 4 3− ions and HA significantly influenced on both As(III) and As(V) removal. • Redox transformation of arsenic in liquid-solid phase was simultaneously investigated. • Respective role of Fe/Mn oxides in OMFM-3 for arsenic removal was identified. [ABSTRACT FROM AUTHOR]

Published
2021
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38. Achieving simultaneous Cu particles anchoring in meso-porous TiO2nanofabrication for enhancing photo-catalytic CO2reduction through rapid charge separation

Author

Xiong, Jinyan, Zhang, Mengmeng, Lu, Mengjie, Zhao, Kai, Han, Chao, Cheng, Gang, and Wen, Zhipan

Abstract

A facile solvo-thermal approach was successfully employed to prepare titanium oxide (TiO2) nano-aggregates with simultaneous copper particles anchoring. The as-synthesized composite could convert CO2into CH4and CO products under simulated solar irradiation. The impact of copper loading amounts on the photo-reduction capability was evaluated. It was found proper amount of Cu loading could enhance the activity of CO2photo-reduction. As a result, the optimal composite (TiO2-Cu-5%) consisting of TiO2supported with 5% (mole ratio) Cu exhibits 2.2 times higher CH4yield and 3 times higher CO yield compared with pure TiO2. Conduction band calculated from the band gap and valence X-ray photoelectron spectroscopy (XPS) indicated TiO2nano-aggregates have suitable band edge alignment with respect to the CO2/CH4and CO2/CO redox potential. Furthermore, with involving of Cu particles, an efficient separation of photo-generated charges was achieved on the basis of photocurrent response and photoluminescence spectra results, which contributed to the improved photo-catalytic performance. The present work suggested that the Cu-decorated TiO2could serve as an efficient photo-catalyst for solar-driven CO2photo-reduction.

Published
2021
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39. Synergistic mediation of metallic bismuth and oxygen vacancy in Bi/Bi 2 WO 6-x to promote 1 O 2 production for the photodegradation of bisphenol A and its analogues in water matrix.

Author

Huang T, Tian F, Wen Z, Li G, Liang Y, and Chen R

Abstract

Bi/Bi 2 WO 6-x heterostructures has been successfully prepared by a facile one-step hydrothermal method. By maneuvering reaction time and Bi/W molar ratio of the precursors, we have been able to selectively introduce oxygen vacancy and metallic Bi into Bi 2 WO 6 nanostructures. The obtained Bi/Bi 2 WO 6-x heterostructures with more oxygen vacancy and moderate metallic Bi exhibit significantly improved photocatalytic activity for the photodegradation of bisphenol A (BPA) and its analogues due to its great ability for the generation of singlet oxygen ( 1 O 2 ), which has proven to work as the main reactive oxygen species during photocatalysis. It is also found the 1 O 2 concentration is highly depended on and modulated by the content of oxygen vacancy and metallic bismuth. Besides, we also demonstrate that the obtained Bi/Bi 2 WO 6-x products display efficient photocatalytic performance toward BPA derivatives degradation and enhanced stability to resist the interferences in the water matrix., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published
2021
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