陆奇
近期热点
资料介绍
个人简历
教育与工作经历\r2019.03~至今 清华大学化学工程系 副教授\r2016.02~2019.03 清华大学化学工程系 助理教授\r2013.09~2016.01 美国哥伦比亚大学化学工程 博士后研究员(双聘)\r2012.02~2016.01 美国特拉华大学生物分子与化学工程系 博士后研究员\r2005.09~2012.02 美国特拉华大学物理与天体物理系 博士\r2000.09~2004.07 浙江大学材料科学与工程系 学士研究领域
"""""Nanostructured electrocatalysts for converting CO2近期论文
Correlating Experimentally Determined CO Adsorption Enthalpy with Electrochemical CO Reduction Performance on Cu Surfaces Xiong H., Sun Q., Chen K., Xu Y., Chang X., Lu Q.*, and Xu B.*, Angewandte Chemie International Edition (2023)\r\rCorrelating CO Coverage and CO Electroreduction on Cu via High-Pressure in Situ Spectroscopic and Reactivity Investigations Hou J., Chang X., Li J., Xu B.*, and Lu Q.*, Journal of the American Chemical Society, 144(48), 22202-22211 (2022)\r\rIntercepting Elusive Intermediates in Cu-Mediated CO Electrochemical Reduction with Alkyl Species Li J., Li C., Hou J., Gao W., Chang X., Lu Q.*, and Xu B.*, Journal of the American Chemical Society, 144(44), 20495-20506 (2022)\r\rProgress and Understanding of CO2/CO Electroreduction in Flow Electrolyzers Wu D., Jiao F.*, and Lu Q.*, ACS Catalysis, 12(20), 12993-13020 (2022)\r\rGaseous CO2 Coupling with N-Containing Intermediates for Key C–N Bond Formation during Urea Production from Coelectrolysis over Cu Yang G. L., Hsieh C. T., Ho Y. S., Kuo T. C., Kwon Y., Lu Q., and Cheng M. J.*, ACS Catalysis, 12(18), 11494-11504 (2022).\r\rEnhancing Hydrogen Oxidation and Evolution Kinetics by Tuning the Interfacial Hydrogen-Bonding Environment on Functionalized Platinum Surfaces Zhao K., Chang X., Su H., Nie Y., Lu Q., and Xu B.*, Angewandte Chemie International Edition, 61(39), e202207197 (2022).\r\rSelective Enhancement of Methane Formation in Electrochemical CO2 Reduction Enabled by a Raman-Inactive Oxygen-Containing Species on Cu He M., Chang X., Chao T. H., Li C., Goddard W. A., Cheng M. J.*, Xu B.*, and Lu Q.*, ACS Catalysis, 12(10), 6036-6046 (2022).\r\rProbing the role of surface speciation of tin oxide and tin catalysts on CO2 electroreduction combining in situ Raman spectroscopy and reactivity investigations He M., Xu B.*, and Lu Q.*, Chinese Journal of Catalysis, 43(6), 1473-1477 (2022).\r\rC-C Coupling Is Unlikely to Be the Rate-Determining Step in the Formation of C2+ Products in the Copper-Catalyzed Electrochemical Reduction of CO Chang X.#, Li J.#, Xiong H., Zhang H., Xu Y., Xiao H., Lu Q.*, and Xu B.*, Angewandte Chemie International Edition, 61(2), e202111167 (2022). (#contributed equally to this work)\r\rInvestigation of electroreduction of carbon dioxide into formate based on machine learning Liu W., Zhang J., Lu Q., and Zhang H.*, CIESC Journal, 72(12), 6262-6273 (2021). \r\rDetermining intrinsic stark tuning rates of adsorbed CO on copper surfaces Chang X., Xiong H., Xu Y., Zhao Y., Lu Q.*, and Xu B.*, Catalysis Science & Technology, 11(20), 6825-6831 (2021).\r\rOxyhydroxide Species Enhances CO₂ Electroreduction to CO on Ag via Coelectrolysis with O₂ Li C., Xiong H., He M., Xu B.*, and Lu Q.*, ACS Catalysis, 11 (19), 12029–12037 (2021) \r\rMachine Learning Investigation of Supplementary Adsorbate Influence on Copper for Enhanced Electrochemical CO₂ Reduction Performance Wu D.#, Zhang J.#, Cheng M. J., Lu Q.*, and Zhang H.*, The Journal of Physical Chemistry C, 125 (28), 15363–15372 (2021) (#contributed equally to this work)\r\rElectrokinetic and In situ Spectroscopic Investigations of CO Electrochemical Reduction on Copper Li J.#, Chang X.#, Zhang H., Malkani A. S., Cheng M., Xu, B.*, and Lu, Q.*, Nature Communications, 12, 3264 (2021) (#contributed equally to this work)\r\rSelective Activation of Propane by Intermediates Generated During Water Oxidation Zhang H., Li C., Lu Q.*, Cheng M. J.*, and Goddard W. A.*, Journal of the American Chemical Society, 143 (10), 3967–3974 (2021)\r\rFirst Principles Study of C-C Coupling Pathways for CO₂ Electrochemical Reduction Catalyzed by Cu(110) Kuo T., Chou, J., Shen M., Hong Z., Chao T., Lu Q.*, and Cheng M.*, The Journal of Physical Chemistry C, 125 (4), 2464–2476 (2021)\r\rEvaluating Potential Catalytic Active Sites on Nitrogen-Doped Graphene for the Oxygen Reduction Reaction: An Approach Based on Constant-Electrode-Potential Density Functional Theory Calculation Chen M., Chao, T., Shen M., Lu Q.*, and Cheng M. J.*, The Journal of Physical Chemistry C, 124 (47), 25675–25685 (2020)\r\rUnderstanding the Electric and Nonelectric Field Components of the Cation Effect on the Electrochemical CO Reduction Reaction Malkani A. S., Li J., Oliveira N. J., He M., Chang X., Xu B.*, and Lu Q.*, Science Advances, 6 (45), eabd2569 (2020) \r\rOxygen Induced Promotion of Electrochemical Reduction of CO₂ via Co-electrolysis He M.#, Li C.#, Zhang H., Chang X., Chen J. G., Goddard W. A., Cheng M. J.*, Xu B.*, and Lu Q.*, Nature Communications, 11, 3844 (2020) (#contributed equally to this work)\r\rTwo-dimensional SnO₂ Nanosheets for Efficient Carbon Dioxide Electroreduction to Formate Li J., Jiao J., Zhang H., Zhu P., Ma H., Chen C., Xiao H.*, and Lu Q.*, ACS Sustainable Chemistry & Engineering, 8 (12), 4975-4982 (2020) 相关热点
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