研究成果
主持基金:
(1)国家自然科学基金(面上项目):基于金属-载体强相互作用构筑抗烧结混合维度异质结及其催化增效机制;项目编号:22172143
(2) 国家自然科学基金(面上项目):化学场驱动催化重整含氧生物质小分子制氢及串联协同降解高盐废水;项目编号:21872123
(3) 国家自然科学基金(青年基金):自由基参与纳米铂基金属表面氰化重构及其抗“甲醇渗透”电催化性能;项目编号:21503189
(4) 浙江省自然科学基金面上项目:纳米金属表面光化学氰基可控改性及电催化特性研究;项目编号:LY15B030009
发表论文:
[1] Renhong Li,* Zhiqi Liu, Quang Thang Trinh, Ziqiang Miao, Shuang Chen, Kaicheng Qian, Roong Jien Wong, Shibo Xi, Yong Yan, Armando Borgna, Shipan Liang, Tong Wei, Yihu Dai, Peng Wang, Yu Tang,Xiaoqing Yan, Tej S. Choksi, and Wen Liu, Strong Metal–Support Interaction for 2D Materials: Application in Noble Metal/TiB2 Heterointerfaces and their Enhanced Catalytic Performance for Formic Acid Dehydrogenation, Advanced Materials, 2021, 33, 2101536.(影响因子:30.2)
[2] Renhong Li, H. Kobayashi, J. Tong, X. Yan, Y. Tang, S. Zou, J. Jin, W. Yi, J. Fan, Radical-involved photosynthesis of AuCN oligomers from Au nanoparticles and acetonitrile, Journal of the American Chemical Society, 134 (2012) 18286-18294. (影响因子:14.7)
[3] Kaicheng Qian, Yong Yan, Shibo Xi, Tong Wei, Yihu Dai, Xiaoqing Yan, Hisayoshi Kobayashi, Sheng Wang, Wen Liu, and Renhong Li*, Elucidating the Strain–Vacancy–Activity Relationship on Structurally Deformed Co@CoO Nanosheets for Aqueous Phase Reforming of Formaldehyde, Small 2021, 2102970. (影响因子:14.1)
[4] R. Li*, X. Zhu, H. Kobayashi, S. Yoshida, W. Chen, L. Du, K. Qian, X. Yan, B. Wu, S. Zou, An Oxygen-Controlled Hydrogen Evolution Reaction: Molecular Oxygen Promotes Hydrogen Production from Formaldehyde Solution Using Ag/MgO Nanocatalyst, ACS Catalysis, 7 (2017) 1478–1484.(影响因子:12.2)
[5] L. Du, K. Qian, X. Zhu, X. Yan, H. Kobayashi, Z. Liu, Y. Lou, and R. Li*, Interface engineering of palladium and zinc oxide nanorods with strong metal–support interactions for enhanced hydrogen production from base-free formaldehyde solution, Journal of Materials Chemistry A, 2019, 7, 8855–8864
(封面论文)(影响因子:10.7)
[6] K. Qian, L. Du, X. Zhu, S. Liang, S. Chen, H. Kobayashi, X. Yan, M. Xu, Y. Dai, R. Li*, Directional oxygen activation by oxygen-vacancyrich WO2 nanorods for superb hydrogen evolution via formaldehyde reforming, Journal of Materials Chemistry A 2019, 7, 14592–14601(影响因子:10.7)
[7] X. Yan, K. Yuan, N. Lu, H. Xu, S. Zhang, N. Takeuchi, H. Kobayashi, R. Li*, The interplay of sulfur doping and surface hydroxyl in band gap engineering: Mesoporous sulfur-doped TiO2 coupled with magnetite as a recyclable, efficient, visible light active photocatalyst for water purification, Applied Catalysis B: Environmental, 218 (2017) 20–31(影响因子:14.2)
[8] X. Zhu, L. Du, Z. Guo, S. Chen, B. Wu, X. Liu, X. Yan, N. Takeuchi, H. Kobayashi, and R. Li*,Tandem catalysis induced by hollow PdO: highly efficient H2 generation coupled with organic dye degradation via sodium formate reforming, Catalysis Science & Technology, 2018, 8, 6217–6227(影响因子:5.7)
[9] R. Li*, X. Zhu, L. Du, K. Qian, B. Wu, S. Kawabata, H. Kobayashi, X. Yan, W. Chen, All-solid-state magnesium oxide supported Group VIII and IB metal catalysts for selective catalytic reforming of aqueous aldehydes into hydrogen, International Journal of Hydrogen Energy, (2017).(影响因子:4.3)
[10] R. Li*, X. Yan, X. Zhu, D. Shou, X. Zhou, Y. Dai, Y. Yang, Gold nanoparticles confined in ordered mesopores: Size effect and enhanced stability during gas-phase selective oxidation of cyclohexanol, Catalysis Today, (2017).(影响因子:4.7)
[11] R. Li, H. Kobayashi, J. Guo, J. Fan, Visible-Light Induced High-Yielding Benzyl Alcohol-to-Benzaldehyde Transformation over Mesoporous Crystalline TiO2: A Self-Adjustable Photo-oxidation System with Controllable Hole-Generation, The Journal of Physical Chemistry C, 115 (2011) 23408-23416.(影响因子:4.5)
[12] R. Li, H. Kobayashi, J. Guo, J. Fan, Visible-light-driven surface reconstruction of mesoporous TiO2: toward visible-light absorption and enhanced photocatalytic activities, Chemical Communications, 47 (2011) 8584-8586.(影响因子:6.3)
[13] R. Li, W. Chen, H. Kobayashi, C. Ma, Platinum nanoparticle loaded bismuth oxide: an efficient plasmonic photocatalyst active under visible light, Green Chemistry, 12 (2010) 212-215. (影响因子:8.6)
[14] X. Yan, X. Zhu, R. Li*, W. Chen*, Au/BiOCl heterojunction within mesoporous silica shell as stable plasmonic photocatalyst for efficient organic pollutants decomposition under visible light, Journal of Hazardous Materials, 303 (2016) 1-9.(影响因子:6.4)
[15] L. Lu, R. Li*, K. Fujiwara, X. Yan, H. Kobayashi, W. Yi, J. Fan, Cyanide Radical Chemisorbed Pt Electrocatalyst for Enhanced Methanol-Tolerant Oxygen Reduction Reactions, The Journal of Physical Chemistry C, 120 (2016) 11572-11580. (影响因子:4.5)
[16] R. Li, H. Kobayashi, X. Yan, J. Fan, Dioxygen activation at room temperature during controllable and highly efficient acetaldehyde-to-acetic acid oxidation using a simple iron (III)–acetonitrile complex, Catalysis Today, 233 (2014) 140-146. (影响因子:4.7)
[17] X. Wang, X. Yan, R. Li*, L. Xiao, G. Ma, Y. Dai, J. Fan, High Density Gold Nanoparticles Within Three-Dimensionally Mesoporous SBA-15: Adsorption Behavior and Optical Properties, Journal of Nanoscience and Nanotechnology, 15 (2015) 7060-7067.
[18] R. Li, W. Chen, W. Wang, Magnetoswitchable controlled photocatalytic system using ferromagnetic Fe 0-doped titania nanorods photocatalysts with enhanced photoactivity, Separation and Purification Technology, 66 (2009) 171-176.
[19] R. Li*, X. Zhu, X. Yan, D. Shou, X. Zhou, W. Chen, Single component gold on protonated titanate nanotubes for surface-charge-mediated, additive-free dehydrogenation of formic acid into hydrogen, RSC Advances, 6 (2016) 100103-100107.
[20] R. Li*, X. Zhu, D. Shou, X. Zhou, X. Yan, The interparticle coupling effect of gold nanoparticles in confined ordered mesopores enhances high temperature catalytic oxidation, RSC Advances, 6 (2016) 88486-88489.
[21] W. Hong, X. Yan, R. Li*, J. Fan, Gold nanoparticle stabilization within tailored cubic mesoporous silica: Optimizing alcohol oxidation activity, Chin. J. Catal. (2017).
[22] W. Yi, X. Yan, R. Li, J.-Q. Wang, S. Zou, L. Xiao, H. Kobayashi, J. Fan, A new application of the traditional Fenton process to gold cyanide synthesis using acetonitrile as a cyanide source, RSC Advances, 6 (2016) 16448-16451.
[23] Y. Tang, S. Xu, Y. Dai, X. Yan, R. Li, L. Xiao, J. Fan, Solid phase metallurgy strategy to sub-5 nm Au–Pd and Ni–Pd bimetallic nanoparticles with controlled redox properties, Chemical Communications, 50 (2014) 213-215.
[24] P. Qiao, S. Xu, D. Zhang, R. Li, S. Zou, J. Liu, W. Yi, J. Li, J. Fan, Sub-10 nm Au–Pt–Pd alloy trimetallic nanoparticles with a high oxidation-resistant property as efficient and durable VOC oxidation catalysts, Chemical Communications, 50 (2014) 11713-11716.
[25] Y. Hong, X. Yan, X. Liao, R. Li*, S. Xu, L. Xiao, J. Fan, Platinum nanoparticles supported on Ca (Mg)-zeolites for efficient room-temperature alcohol oxidation under aqueous conditions, Chemical Communications, 50 (2014) 9679-9682.
[26] S. Zou, R. Li, H. Kobayashi, J. Liu, J. Fan, Photo-assisted cyanation of transition metal nitrates coupled with room temperature C–C bond cleavage of acetonitrile, Chemical Communications, 49 (2013) 1906-1908.
[27] X. Yan, X. Wang, Y. Tang, G. Ma, S. Zou, R. Li, X. Peng, S. Dai, J. Fan, Ordered, extra-large mesopores with highly loaded gold nanoparticles: a new sintering-and coking-resistant catalyst system, Chemical Communications, 49 (2013) 7274-7276.
[28] X. Yan, X. Wang, Y. Tang, G. Ma, S. Zou, R. Li, X. Peng, S. Dai, J. Fan, Unusual Loading-Dependent Sintering-Resistant Properties of Gold Nanoparticles Supported within Extra-large Mesopores, Chem Mater, 25 (2013) 1556-1563.
[29] J. Wang, X. Liu, R. Li, P. Qiao, L. Xiao, J. Fan, TiO2 nanoparticles with increased surface hydroxyl groups and their improved photocatalytic activity, Catal Commun, 19 (2012) 96-99.
[30] S. Zou, J. Liu, H. Kobayashi, C. Chen, P. Qiao, R. Li, L. Xiao, J. Fan, Boosting Hydrogen Evolution Activities by Strong Interfacial Electronic Interaction in ZnO@ Bi (NO3) 3 Core–Shell Structures, The Journal of Physical Chemistry C, (2017).
