徐勇-广东工业大学研究生招生信息网

徐勇

作者：时间：2021-03-09 点击数：

		徐勇教授
		所属学院：	材料与能源学院
		导师类别：	博士生导师/硕士生导师
		科研方向：	纳米催化、能源材料
		联系方式：	yongxu@gdut.edu.cn
		招生学院：	材料与能源学院

个人简述	课题组聚焦于贵金属纳米催化剂的设计、可控合成、结构调控及构效关系研究。利用多种原位表征方法研究催化剂界面构效关系及催化作用机理，并积极探索在石油化工、新型清洁能源及环境保护等领域的应用。主要研究方向： 1、贵金属纳米催化剂可控合成与结构调控； 2、无机功能纳米催化剂的表界面改性及其在能源与催化方面的应用

学科领域	科学学位：材料科学与工程专业学位：材料工程

教育背景	2013年6月中国科学技术大学可再生洁净能源专业获博士学位 2011年9月-2012年9月意大利国家核物理研究院Frascati国家实验室联合培养博士

工作经历	2020年9月-至今广东工业大学材料与能源学院教授 2017年7月-2020年8月苏州大学副教授 2016年5月-2017年6月苏州大学博士后 2015年3月-2017年4月美国劳伦斯伯克利国家实验室博士后 2014年3月-2017年2月苏州大学博士后 2013年9月-2014年2月中科院上海高等研究院助理研究员

学术兼职	eScience青年编委


主要论文	[1] Y. Feng, Y. Ji, Y. Zhang, Q. Shao, Y. Xu,* Y. Li, X. Huang. Synthesis of noble metal chalcogenides via cation exchange reactions. Nature Synthesis, 2022, 1, 626–634. [2] J. Wang, H. Yang, F. Li, L. Li, J. Wu, S. Liu, T. Cheng, Y. Xu, Q. Shao, X. Huang, Single-site Pt-doped RuO2 hollow nanospheres with interstitial C for high performance acidic overall water splitting, Science Advances, 2022, 8(9), eabl9271-eabl9271. [3] T. Yang, X. Mao, Y. Zhang, X. Wu, L. Wang, M. Chu, C. W. Pao, S. Yang, Y. Xu,* X. Huang, Coordination tailoring of Cu single sites on C₃N₄ realizes selective CO₂ hydrogenation at low temperature, Nature Communications, 2021, 12, 6022. [4] S. Liu, S. Geng L. Li, Y. Zhang G. Ren, B. Huang, Z. Hu, J. F. Lee, Y. H. Lai, Y. H. Chu, Y. Xu,* Q. Shao, X. Huang, A top-down strategy for amorphization of hydroxyl compounds for electrocatalytic oxygen evolution, Nature Communications, 2022, 13, 1187. [5] S. Bai, F. Liu, B. Huang, F. Li, H. Lin, T. Wu, M. Sun, J. Wu, Q. Shao, Y. Xu,* X. Huang, High-efficiency direct methane conversion to oxygenates on a cerium dioxide nanowires supported rhodium single-atom catalyst, Nature Communications, 2020, 11, 954. [6] S. Bai, Y. Xu, K. Cao, X. Huang, Selective Ethanol Oxidation Reaction at the Rh–SnO₂ Interface, Advanced Materials, 2021, 33(5), 2005767. [7] Z. Yu, S. Lv, Q. Yao, N. Fang, Y. Xu, Q. Shao, C. W. Pao, J. F. Lee, G. Li, L. Yang,* X. Huang,* Low-coordinated Pd site within amorphous palladium selenide for active, selective and stable H₂O₂ electrosynthesis. Advanced Materials, 2023, 35(6), 2208101. [8] J. Zhang, X. Mao, S. Wang, L. Liang, M. Cao, L. Wang, G. Li, Y. Xu, X. Huang, Hydrogen Evolution Hot Paper Superlattice in a Ru Superstructure for Enhancing Hydrogen Evolution. Angewandte Chemie International Edition* 2022, 61, e202116867. [9] Y. Jin, P. Wang, X. Mao, S. Liu, L. Li, L. Wang, Q. Shao, Y. Xu, X. Huang, A top-down strategy to realize surface reconstruction of small- sized platinum-based nanoparticles for selective hydrogenation, Angewandte Chemie International Edition, 2021, 133(32), 17570-17574. [10] C. Zhan^#, Y. Xu^#, L. Bu, H. Zhu, Y. Feng, T. Yang, Y. Zhang, Z. Yang, B. Huang, Q. Shao, X. Huang, Subnanometer high-entropy alloy nanowires enable remarkable hydrogen oxidation catalysis, Nature Communications, 2021, 12, 6261. [11] M. Wang^#, Y. Xu^#, C. Peng, S. Chen, Y. Lin, Z. Hu, L. Sun, S. Ding, C. W. Pao, Q. Shao, X. Huang, Site-specified two-dimensional heterojunction of Pt nanoparticles/metal-organic frameworks for enhanced hydrogen evolution, Journal of the American Chemical Society, 2021, 143(40), 16512-16518. [12] J. Zhang, G. Ren, D. Li, Q. Kong, Z. Hu, Y. Xu, S. Wang, L. Wang,* M. Cao, X. Huang,* Interface engineering of snow-like Ru/RuO₂ nanosheets for boosting hydrogen electrocatalysis. Science Bulletin, 2022, 67, 2103-2111. [13] H. Peng, T. Yang, H. Lin, Y. Xu,* Z. Wang, Q. Zhang, S. Liu, H. Geng, . Gu, C. Wang, X. Fan,* W. Chen, X. Huang. Ru/In dual-single atoms modulated charge separation for significantly accelerated photocatalytic H₂ evolution in pure water. Advanced Energy Materials, 2022, 12, 2201688. [14] S. Liu, Y. Zhang, X. Mao, L. Li, Y. Zhang, L. Li, Y. Pan, X. Li, L. Wang, Q. Shao, Y. Xu, X. Huang, Ultrathin perovskite derived Ir-based nanosheets for high-performance electrocatalytic water splitting, Energy & Environmental Science, 2022, 15(4), 1672-1681. [15] M. Wang, L. Liang, X. Liu, Q. Sun, M. Guo, S. Bai, Y. Xu. Selective semi-hydrogenation of alkynes on palladium-selenium nanocrystals. Journal of Catalysis, 2023, 418, 247-255. [16] M. Chu, Q. Pan, W. Bian, Y. Liu, M. Cao, C. Zhang, H. Lin, Y. Xu,* Strong metal-support interaction between palladium and gallium oxide within monodisperse nanoparticles, Self-supported catalysts for propyne semi-hydrogenation, Journal of Catalysis, 2021, 395, 36-45. [17] Y. Dong, Q. Sun, C. Zhan, J. Zhang, H. Yang, T. Cheng, Y. Xu,* Z. Hu, C. W. Pao, H. Geng, X. Huang, Lattice and Surface Engineering of Ruthenium Nanostructures for Enhanced Hydrogen Oxidation Catalysis. Advanced Functional Materials, 2022, https://doi.org/10.1002/adfm.202210328. [18] P. Li, X. Liu, M. Guo, Y. Pi, N. Wang, S. Bai, Y. Xu, Qi Sun. Stable and ordered body-centered cubic PdCu phase for highly selective hydrogenation. Small Methods, 2022, 2201356 (front inside cover). [19] K. Wang, S. Liu, J. Zhang, Z. Hu, Q. Kong, Y. Xu, X. Huang. A one-stone-two-birds strategy to functionalized carbon. ACS Nano, 2022, 16, 15008–15015. [20] M. Wang, L. Lü, Q. Jiang, G. Li, Q. Hong, M. Wang, Y. Xu, X. Huang, Kinetics-Induced Orientational Morphological Evolution of Pd-Sb Rhombohedra from Regular Nanocrystals to Distorted Ones, Science China Materials, 2022, https://doi.org/10.1007/s40843-022-2334-4. [21] J. Zhang, X. Fan, S. Wang, M. Cao, L. Bu, Y. Xu, H. Lin, X. Huang. Surface engineered Ru₂Ni multilayer nanosheets for hydrogen oxidation catalysis. CCS Chemistry, 2022, 10.31635/ccschem.022.202202269. [22] L. Ling, M. Chu, R. Song, S. Liu, G. Ren, Y. Xu,* L. Wang, Q. Xu, Q. Shao, J. Lu, X. Huang, CO spillover on ultrathin bimetallic Rh/Rh-M nanosheets. Chem Catalysis, 2022, 2(7),1709-1719. [23] T. Yang, H. Zhang, C. Zhan, L. Liang, Y. Xu, P. Ruan, Y. Zhang, J. Li, L. Wang, X. Lv, S. Yang, C. Pao, X. Huang. Strong synergy between single atoms and single-atom alloys enables active and selective H₂O₂ synthesis. Chem Catalysis, 2022, 2(12), 3607-3620. [24] S. Feng, S. Ning, L. Wang, J. Zhao, J. Ou, Z. Wu, S. Luo, Z. Lin, K. Yan, C. Wu, and Y. Xu, Modifying CsPbX₃ (X = Cl, Br, I) with a Zeolitic Imidazolate Framework through Mechanical Milling for Aqueous Photocatalytic H₂ Evolution, ACS Appl. Energy Mater. 2022, 5, 6248–6255. [25] Y. Xu, X. Wang, D. Yang, Z. Tang, M. Cao, H. Hu, L. Wu, L. Liu, J. McLeod, H. Lin, Y. Li, Y. Lifshitz, T. K. Sham, Q. Zhang, Stabilizing oxygen vacancies in ZrO₂ by Ga₂O₃ boosts the direct dehydrogenation of light alkanes, ACS Catalysis, 2021, 11(16), 10159-10169. [26] K. Wang, H. Yang, J. Zhang, G. Ren, T. Cheng, Y. Xu,* X. Huang. The exclusive surface and electronic effects of Ni on promoting the activity of Pt towards alkaline hydrogen oxidation, Nano Research, 2022, 15, 5865–5872. [27] Q. Yao, Z. Yu, Y. Lai, Y. Chu, T. Chan, Y. Xu, Q. Shao, X. Huang, S incorporated RuO₂-based nanorings for active and stable water oxidation in acid, Nano Research, 2022, 15(5), 3964-3970. [28] Y. Xu, M. Cao, S. Huang,Recent advances and perspective on the synthesis and photocatalytic application of metal halide perovskite nanocrystals, Nano Research, 2021, 14(11), 3773-3794. [29] J. Gong, M. Chu, W. Guan, Y. Liu, Q. Zhong, M. Cao, Y. Xu, Regulating the interfacial synergy of Ni/Ga₂O₃ for CO₂ hydrogenation toward the reverse water–gas shift reaction, Industrial & Engineering Chemistry Research, 2021, 60(26), 9448-9455. [30] M. Chu, Y. Liu, J. Gong, C. Zhang, X. Wang, Q. Zhong, Li. Wu, Y. Xu,* Suppressing Dehydroisomerization boosts n-butane dehydrogenation with high butadiene Selectivity, Chemistry–A European Journal, 2021, 27(45), 11643-11648. [31] Q. Yao, B. Huang, Y. Xu,* L. Li, Q. Shao, X. Huang, A chemical etching strategy to improve and stabilize RuO2-based nanoassemblies for acidic oxygen evolution, Nano Energy, 2021, 84, 105909. [32] K. Cao, H. Yang, S. Bai, Y. Xu, C. Yang, Y. Wu, M. Xie, T. Cheng, Q. Shao, X. Huang, Efficient Direct H₂O₂ Synthesis Enabled by PdPb Nanorings via Inhibiting the O−O Bond Cleavage in O₂ and H₂O₂, ACS Catalysis, 2021, 11(3), 1106-1118. [33] L.g Wu, M. Chu, J. Gong, M. Cao, Y. Liu, Y. Xu,* Regulation of surface carbides on palladium nanocubes with zeolitic imidazolate frameworks for propyne selective hydrogenation, Nano Research, 2021, 14(5), 1559-1564. [34] W. Ji, C. Zhan, Y. Xu,* D. Li, Y. Zhang, L. Wang , L. Liu , Y. Wang, W. Chen, H. Geng, X. Huang , Phase and interface engineering of nickel carbide nanobranches for efficient hydrogen oxidation catalysis, Journal of Materials Chemistry A, 2021, 9(46), 26323-26329. [35] Y. Pi^#, Y. Xu^#, L. Li, T. Sun, B. Huang, L. Bu, Y. Ma, Z. Hu, C.W. Pao, X. Huang, Selective surface reconstruction of a defective iridium‐based catalyst for high-efficiency water splitting, Advanced Functional Materials, 2020, 30(43), 2004375 (equal contribution). [36] Y. Xu,* M. Cao, Q. Zhang, Recent advances and perspective on heterogeneous catalysis using metals and oxide nanocrystals, Materials Chemistry Frontiers, 2021, 5(1), 151-222. [37] Y. Xu, M. Chu, F. Liu, X. Wang, Y. Liu, M. Cao, J. Gong, J. Luo, H. Lin, Y. Li, Q. Zhang, Revealing the correlation between catalytic selectivity and the local coordination environment of Pt single atom, Nano Letters, 2020, 20(9), 6865-6872. [38] S. Bai, M. Xie, T. Cheng, K. Cao, Y. Xu, X. Huang, Surface engineering of RhOOH nanosheets promotes hydrogen evolution in alkaline, Nano Energy, 2020, 78, 105224. [39] M. Cao, Y. Damji, C. Zhang, L. Wu, Q. Zhong, P. Li, D. Yang, Y. Xu, Q. Zhang, Low-Dimensional‐Networked Cesium Lead Halide Perovskites, Properties, Fabrication, and Applications, Small Methods, 2020, 4(12), 2000303. [40] S. Bai, Q. Yao, Y. Xu, K. Cao, X. Huang, Strong synergy in a lichen-like RuCu nanosheet boosts the direct methane oxidation to methanol, Nano Energy*, 2020, 71, 104566.

知识产权	[1] 一种丁烷催化脱氢制备丁烯和丁二烯的方法，CN109608301B [2] 一种低碳烷烃脱氢催化剂及制备低碳烯烃的方法 CN109603898B

科研项目	[1] 广东省自然基金杰出青年基金 [2] 国家自然科学基金青年项目 [3] 江苏省自然科学基金青年项目 [4] 江苏省双创博士