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Hauptverfasser: Yuanzong Shen, Enze Li, Siyuan Feng, Yuhao Li, Weichen Li, Weiping Xiao, Guangrui Xu, Dehong Chen, Fusheng Liu, Lei Wang, Zexing Wu
Format: Artículo Open Access
Veröffentlicht: Wiley 2026
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Online-Zugang:https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.70672
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author Yuanzong Shen
Enze Li
Siyuan Feng
Yuhao Li
Weichen Li
Weiping Xiao
Guangrui Xu
Dehong Chen
Fusheng Liu
Lei Wang
Zexing Wu
author_facet Yuanzong Shen
Enze Li
Siyuan Feng
Yuhao Li
Weichen Li
Weiping Xiao
Guangrui Xu
Dehong Chen
Fusheng Liu
Lei Wang
Zexing Wu
Yuanzong Shen
Enze Li
Siyuan Feng
Yuhao Li
Weichen Li
Weiping Xiao
Guangrui Xu
Dehong Chen
Fusheng Liu
Lei Wang
Zexing Wu
collection Wiley Open Access
contents Microwave Quasi‐Solid State to Construct Boron‐Doped Black TiO 2 Supported Ru as Advanced Electrocatalyst for Seawater Hydrogen Generation Yuanzong Shen Enze Li Siyuan Feng Yuhao Li Weichen Li Weiping Xiao Guangrui Xu Dehong Chen Fusheng Liu Lei Wang Zexing Wu ChemSusChem Metal oxides have emerged as the dominant choice of matrix for the design and synthesis of supported catalysts with high‐performance, because of the tunable surface properties, low cost, and strong interactions with active components. Herein, the nanoflower‐like titanium dioxide (TiO 2 ) is achieved through solvothermal approach. Then, boron (B) doped black TiO 2 loaded with Ru (Ru/B‐TiO 2 ) is achieved through rapid (40 s) microwave quasi‐solid approach. The incorporation of B modulates the energy band structure of the electrocatalyst, creating additional active sites, and then favors the water dissociation and following hydrogen desorption. The presence of oxygen vacancy defects and metal‐support interactions (MSI) lead to satisfactory stabilization of the catalysts. These effects collectively contributed to the superior performance in 1 M KOH and alkaline seawater for the hydrogen evolution reaction (HER) with small overpotentials of 39 and 61 mV, respectively, which also demonstrates excellent activity and stability. This work presents a novel microwave‐assisted strategy for constructing metal oxide supported low‐content noble metals for energy conversion and storage applications. 10.1002/cssc.70672 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/cssc.70672
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spellingShingle Microwave Quasi‐Solid State to Construct Boron‐Doped Black TiO 2 Supported Ru as Advanced Electrocatalyst for Seawater Hydrogen Generation
Yuanzong Shen
Enze Li
Siyuan Feng
Yuhao Li
Weichen Li
Weiping Xiao
Guangrui Xu
Dehong Chen
Fusheng Liu
Lei Wang
Zexing Wu
ChemSusChem
Microwave Quasi‐Solid State to Construct Boron‐Doped Black TiO 2 Supported Ru as Advanced Electrocatalyst for Seawater Hydrogen Generation Yuanzong Shen Enze Li Siyuan Feng Yuhao Li Weichen Li Weiping Xiao Guangrui Xu Dehong Chen Fusheng Liu Lei Wang Zexing Wu ChemSusChem Metal oxides have emerged as the dominant choice of matrix for the design and synthesis of supported catalysts with high‐performance, because of the tunable surface properties, low cost, and strong interactions with active components. Herein, the nanoflower‐like titanium dioxide (TiO 2 ) is achieved through solvothermal approach. Then, boron (B) doped black TiO 2 loaded with Ru (Ru/B‐TiO 2 ) is achieved through rapid (40 s) microwave quasi‐solid approach. The incorporation of B modulates the energy band structure of the electrocatalyst, creating additional active sites, and then favors the water dissociation and following hydrogen desorption. The presence of oxygen vacancy defects and metal‐support interactions (MSI) lead to satisfactory stabilization of the catalysts. These effects collectively contributed to the superior performance in 1 M KOH and alkaline seawater for the hydrogen evolution reaction (HER) with small overpotentials of 39 and 61 mV, respectively, which also demonstrates excellent activity and stability. This work presents a novel microwave‐assisted strategy for constructing metal oxide supported low‐content noble metals for energy conversion and storage applications. 10.1002/cssc.70672 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Microwave Quasi‐Solid State to Construct Boron‐Doped Black TiO 2 Supported Ru as Advanced Electrocatalyst for Seawater Hydrogen Generation
topic ChemSusChem
url https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.70672