林旭锋个人简历



林旭锋，男，博士，教授，博士生导师；任教于中国石油大学（华东）理学院化学系。主要从事与石油、天然气、生物质等碳基能源原料增值转化以及与节能、环保过程相关的纳米催化剂制备、催化性能与反应机理的理论与实验研究，具体包含：
(1) 发展新型催化材料制备方法，实现催化活性组分的原子级分散，为提高催化活性以及研究构效关系打下基础；并将相关催化剂用于碳基能源分子的催化转化性能研究。
(2) 发展催化剂活性组分的后续修饰加工法，改变活性组分的催化稳定性以及产物选择性，从而为发展更高效、节能化工生产、环保过程奠定技术基础。
(3) 利用量子化学第一性原理的方法，研究设计途径的动力学与热力学曲线特征，判断催化反应体系的反应机理，为开发高性能催化材料打下理论基础；通过理论与实验联合研究，认识、帮助设计催化剂活性位结构。
以第一作者或通讯作者为主发表学术论文约50篇，申请专利14项；主持国家级基金项目2项，省部级基金项目2项；获得厅局级自然科学奖励一项。
联系方式：
Email: hatrick2009@upc.edu.cn(优先)；
QQ：。
教育经历：
2003/9 - 2007/9，香港大学，物理化学，博士，导师：Prof. David L. Phillips；
2000/9 - 2003/7，厦门大学，物理化学，硕士，导师：田中群院士；
1996/9 - 2000/7，厦门大学，化学，学士。
工作经历：
2016/1-至今，中国石油大学（华东），理学院化学系，教授；
2009/9 -2015/12，中国石油大学（华东），理学院化学系（2011年前为化学化工学院化学系），副教授；
2007/10-2009/08，西北大学（美国），催化中心（能源过程的催化研究所），博士后。
主持或参加科研项目情况：
1、国家自然科学基金面上项目，**、用于轻烷烃脱氢的单金属中心铬催化剂：制备、结构及构效关系、2016/01-2019/12、77万元、主持。
2、国家自然科学青年基金，**、双功能催化剂用于多元醇和单糖的加氢脱氧催化反应研究、2011/01-2013/12、21万元、主持。
3、山东省自然基金面上项目，ZR2014BM002、单金属中心铬基催化剂的制备及其对轻烷烃脱氢的催化机理研究、2014/12-2017/12、17万元、主持。
4、教育部留学归国人员科研启动基金，糖/多元醇的催化氢化脱氧反应的机理研究和催化剂开发；2010/12-2013/12、3万元、主持。
5、中国石油大学(华东)自主创新、15CX05052A、单一位钒催化剂上的小分子烷烃脱氢：催化剂制备与反应机理、2015/09-2018/09、10万元、主持。
6、中国石油大学(华东)自主创新、11CX04068A、新型过渡金属催化剂上小分子烷烃氧化脱氢反应机理研究；2011/04-2013/03、6万元、主持。
7、山东省自然基金青年基金，气相沉积法构建负载型亚纳米级过渡金属催化剂；ZR2012BQ020、2012/07-2015/07、5万元、参与（位次2/5）。
8、国家油气重大专项项目，海上稠油热采复合增效技术研究，2016.01~ 2020.12；参与（位次3/17）；总经费：269.87万元。
9、中石油重大科技专项，FDS-2硫化型柴油加氢催化剂制备技术开发与工业应用，2010.01~2014.12，参与（位次13/17）；总结费：1046万元。
发表科研论文：
2016~present
(1) Unraveling how the H₂-treatment helps improve the performances of Cu andAg loaded Y zeolites for adsorptive desulfurization,
Zhengjian Hou, Ling Wei, Xinyuan Feng, Neng Qin, Yanyan Xi^*, Xufeng Lin*, Chuangye Wang, ACS Omega, 2020, 5, 6309-6320.
(2) The electronic and steric effects of neutral and ionic phosphines on Ir(I)-complex catalyzed hydroaminomethylation of olefins
Huan Liu, Da Yang, Yixuan Yao, Yongqiang Xu, Hongyan Shang*, Xufeng Lin*, Molecular Catalysis, 2020, 485, 110843.
(3) Remote Directed Isocyanation of Unactivated C(sp3)-H Bonds: Forging Seven-Membered Cyclic Ureas Enabled by Copper Catalysis, Hongwei Zhang,PeiyuanTian, Lishuang Ma, Yulu Zhou, Cuiyu Jiang, Xufeng Lin, Xiao Xiao, Organic Letters, 2020, 22, 997-1002.
(4) UiO-66 supported Fe catalyst: A vapor deposition preparation method and its superior catalytic performance for removal of organic pollutants in water
Huimin Zhuang, Bili Chen, Wenjin Cai,Yanyan Xi^*, Tianxu Ye, Chuangye Wang, Xufeng Lin*, R. Soc. open sci. 2019, 6, 182047.
(5) SiO₂-Modified Pt/Al₂O₃for Oxidative Dehydrogenation of Ethane: A Preparation Method for Improved Catalytic Stability, Ethylene Selectivity, and Coking Resistance
Yanyan Xi,Jianmei Xiao, Xufeng Lin*, Weining Yan, Chuangye Wang, Chenguang Liu, Industrial & Engineering Chemistry Research2018,57,10137-10147
(6) Surface concentration or surface excess, which one dominates the surface tension of multicomponent mixtures?
Chuangye Wang, Xueling, Wang, Feng Liu, Zhiyang Jiang, Xufeng Lin, Coll. Poyl. Sci.2018, 296, 89-93.
(7) Methane activation on nickel oxide clusters with a concerted mechanism: a density functional theory study of the effect of silica support.
Yanyan Xi, Bili Chen, Xufeng Lin*, Chuangye Wang, Hui Fu, J. Mol. Model.2016,22, R79.
(8) The substituent effect of the pentafluorophenyl groups on ruthenium- porphyrin- catalyzed intramolecular amidation of sulfamate ester: A DFT study.
Xufeng Lin*,Bili Chen, Yanyan Xi, Chuangye Wang, Hui Fu, Comp. Theo. Chem.2016, 1080, 1-9.
(9) The effect of a silica support: a density functional theory study of the C-H bond activation of ethane on a nickel oxide cluster,
Xufeng Lin*,Bili Chen, Yanyan, Xi, David L. Phillps, Wenyue Guo, J. Phys. Org. Chem. 2016, 29, 134-144.
(10) A density functional theory study on the effect of silica support: Methane activation on nickel oxide clusters through a radical mechanism.
Yanyan Xi, Bili Chen, Xufeng Lin*, Hui Fu, Chuangye Wang, Comp. Theo. Chem.2016, 1076, 65-73.
(11) Surface structure of aqueous ionic surfactant solutions and effects of solvent therein-a computer simulation study
Chuangye Wang, Zhiyang Jiang, Ling Xu, Aiting Kan, Hui Fu, Xufeng Lin,
Coll. Poly. Sci. 2016, 294,575-581.

2011-2015
(1) Molecular structure of ionic surfactant solution surface and effects of counter-ion therein-a joint investigation by simulation and experiment
Chuangye Wang, Yajie, Tan, Zhiyang Jiang, Xufeng Lin,Songqing Hu,Coll. Poly. Sci. 2015, 293,3479-3486.
(2) Using neutral impact collision ion scattering spectroscopy and angular resolved X-ray photoelectron spectroscopy to analyze surface structure of surfactant solutions
Chuangye Wang, Aiting Kan, Zhen Liu, Guodong Zhang, Xufeng Lin,Hui Fu,Coll. Poly. Sci. 2015, 293,1655-1666.
(4) A reaction mechanism of methane coupling on a silica supported single-site tantalum catalyst
X. F. Lin*, Y. Y. Xi. G. D. Zhang. D. L. Phillips, W. Y. Guo，Organometallics, 2014, 33, 2172?2181.
(5) Hydrogenolysis of Glycerol by the Combined Use of Zeolite and Ni/Al₂O₃as Catalysts: A Route for Achieving High Selectivity to 1?ropanol
X. F. Lin*, Y. H. Lv, Y. Y. Xi, Y. Y. Qu, D. L. Phillips, C. G. Liu，Energy & Fuels, 2014, 28, 3345?3351.
(6) Alumina-supported Fe catalyst prepared by vapor deposition and its catalytic performance for oxidative dehydrogenation of ethane
L. Y. Xu, X. F. Lin*, Y. Y. Xi, X. M. Lu, C. G. Liu，Materials Research Bulletin, 2014, 59, 254-260.
(7) Acid catalyzed first dehydration of glycerol at the secondary site: the effect of glycerol conformation
X. F. Lin*, Y. Y. Qu, Y. Y. Xi, C. G. Liu, Journal of Theoretical and Computational Chemistry, 2014, 13, **-1~**-15.
(8) Controllable synthesis of Zn_xCd_1-xS nanowires with tunable optical properties
X. F. Lin, Y. Y. Xi, D. L. Lin，Acta Phys. -Chim. Sin. 2014,30,576-582.
(9) A combined experimental and computational study on the catalytic dehydration of glycerol on microporous zeolites: An investigation of the reaction mechanism and acrolein selectivity
X. F. Lin*, Y. H. Lv, Y. Y. Qu, G. D. Zhang, Y. Y. Xi, D. L. Phillips, C. G. Liu, Phys. Chem. Chem. Phys.,2013, 15, 20120.
(10) The first dehydration and the competing reaction pathways of glucose homogeneously and heterogeneously catalyzed by acids
X. F. Lin*, Y. Y. Qu, Y. H. Lv, Y. Y. Xi, D. L. Phillips, C. G. Liu, Phys. Chem. Chem. Phys.,2013, 15, 2967.
(11) Unraveling the reaction mechanism for nickel-catalyzed oxidative dehydrogenation of ethane by DFT: The C-H bond activation step and its following pathways
X. F. Lin*, Y. Y. Xi, J. Sun, J. Phys. Chem. C, 2012, 116, 3503.
(12) A computational study on the competing intramolecular amidation and aziridination reactions catalyzed by dirhodium tetracarboxylate
X. F. Lin*, Y. Y. Xi, J. Sun, Computational and Theoretical Chemistry, 2012, 999, 74.
(13) Theoretical study on the hypervalent lambda(3)-bromane strategy for Baeyer-Villiger oxidation of benzaldehyde and acetaldehyde: rearrangement mechanism
H. Fu, S. W. Xie, A. P. Fu, X. F. Lin, H. Zhao, T. X. Ye, Organic and Biomolecular Chemistry, 2012, 10, 6333.
(14) Computational interpretation of the stereoselectivity for a dirhodium tetracarboxylate- catalyzed amidation reaction, X. F. Lin*, J. Sun, Y. Y. Xi, Bo Pang,
Computational and Theoretical Chemistry, 2011, 963, 284.
(15) How racemic secondary alkyl electrophiles proceed to enantioselective products in Negishi cross-coupling reactions, X. F. Lin*, J. Sun, Y. Y. Xi, D. L. Lin
Oragnometallics, 2011, 30, 3284.

2010 and before
(1) Oxidative dehydrogenation of ethane with oxygen catalyzed by K-Y zeolite supported first-row transition metals
X. F. Lin, K. R. Poeppelmeier, E. Weitz,Applied catalysis A-General, 2010, 381, 114.
(2) Oxidative dehydrogenation (ODH) of ethane with O₂as oxidant on selected transition metal-loaded zeolites,
X. F. Lin, C. A. Hoel, W. M. H. Sachtler, K. R. Poeppelmeier, E. Weitz, Journal of Catalysis, 2009, 265, 54.
(3) A DFT Study on the Mechanism of Rh2(II,II)-Catalyzed Intramolecular Amination of Carbamates
X. F. Lin, C. Y. Zhao, C. M. Che, Z. F. Ke, D. L. Phillips, Chem. Asian J.2007, 2, 1101.
(4) Surface-enhanced Raman scattering in the ultraviolet spectral region: UV-SERS on rhodium and ruthenium electrodes
B. Ren, X. F. Lin, Z. L. Yang, G. K. Liu, R. F. Aroca, B. W. Mao, Z. Q. Tian, J. Am. Chem. Soc.2003, 125, 9598.
(5) Electrochemical and surface-enhanced Raman spectroscopic studies on the adsorption and electrooxidation of C₁molecules on a roughened Rh electrode
X. F. Lin, B. Ren, Z. Q. Tian, J. Phys. Chem. B2004, 108, 981.
(6) Reaction mechanism and stereoselectivity of ruthenium-Porphyrin-catalyzed intramolecular amidation of sulfamate ester: A DFT computational study
X. F. Lin, C. M. Che, D. L. Phillips,J. Org. Chem., 2008, 73, 529.
(7) Density functional theory study of water-assisted deprotonation of the C8- intermediate in the reaction of the 2-Fluorenylnitrenium ion with guanosine to form a C8 adduct
Z. Guo, X. F. Lin, C. Y. Zhao, D. L. Phillilps, Journal of Molecular Structure- Theochem, 2008, 848, 119.
(8) Density functional theory studies of negishi alkyl-alkyl cross-coupling reactions catalyzed by a methyiterpyridyl-Ni(I) complex,
X. F. Lin, D. L. Phillips, J. Org. Chem., 2008, 73, 3680
(9) Modeling S_N2 reactions in methanol solution by ab initio calculation of nucleophile solvent-substrate clusters
X. F. Lin, C. Y. Zhao, D. L. Phillips, J. Org. Chem., 2005, 70, 9279.
(10) Water-catalyzed O-H Insertion/HI elimination reactions of isodihalomethanes (CH2X-I, where X = Cl, Br, I) with water and the dehalogenation of dihalomethanes in water-solvated environments
X. F. Lin, X. G. Guan, W. M. Kwok. C. Y. Zhao, Y. Du, Y. L. Li, D. L. Phillips, J. Phys. Chem. A, 2005, 109, 981.
(11) Water-catalyzed dehalogenation reactions of the isomer of CBr4 and its reaction products and a comparison to analogous reactions of the isomers of di- and trihalomethanes,
C. Y. Zhao, X. F. Lin, W. M. Kwok, X. G. Guan, Y. Du, D. Q. Wang, K. F. Hung, D. L. Phillips, Chem. Euro. J., 2005, 11, 1093.
(12) An ab initio study of the reactions of CH2X-X (X = Cl, Br, I)isopolyhalomethanes with nCH₃OH
X. F. Lin, C. Y. Zhao, D. L. Phillips, Molecular Simulation, 2005, 31, 483.
(13) Ab initio investigation of the O-Y (Y = CH3, H) insertion/HI elimination reactions of CH2I-I with CH3OH and H2O: comparison of methanol and water catalyzed reactions
X. F. Lin, C. Y. Zhao, D. L. Phillips,Chem. Phys. Lett.2004, 397, 488.
(14) Ultraviolet photolysis of CH2I2 in methanol: O-H insertion and HI elimination reactions to form a dimethoxymethane product
X. G. Guan, X. F. Lin, W. M. Kwok, Y. Du, Y. L. Li, C. Y. Zhao, D. Q. Wang, D. L. Phillips J. Phys. Chem. A2005, 109, 1247
(15) Surface-enhanced Raman spectroscopy with ultraviolet excitation
X. F. Lin, B. Ren, Z. L. Yang, G. K. Liu, Z. Q. Tian, J. Raman Spectrosc.2005, 36, 606.
(16) Electrochemically roughened rhodium electrode as a substrate for surface-enhanced Raman spectroscopy
B. Ren, X. F. Lin, J. W. Yan, B. W. Mao, Z. Q. Tian, J. Phys. Chem. B2003, 107, 899.
(17) Optimizing detection sensitivity on surface-enhanced Raman scattering of transition-metal electrodes with confocal Raman microscopy
B. Ren, X. F. Lin, Y. X. Jiang, P. G. Cao, Y. Xie, Q. J. Huang, Z. Q. Tian, Appl. Spectrosc. 2003, 57, 419.
(18) An investigation of the adsorption of pyrazine and pyridine on nickel electrodes by in situ surface-enhanced Raman spectroscopy
Q. J. Huang, X.F.Lin, Z. L. Yang, J. W. Hu, Z. Q. Tian, J. Electroanal. Chem.2004, 563, 121.
(19) Probing different adsorption behavior of CO on Pt at solid/liquid and solid/gas interfaces by Raman spectroscopy with a three-phase Raman cell
B. Ren, L. Cui, X. F. Lin, Z. Q. Tian, Chem. Phys. Lett.2003, 376, 130.
(20) Surface-enhanced Raman scattering from transition metals with special surface morphology and nanoparticle shape
Z. Q. Tian, Z. L. Yang, B. Ren, J. F. Li, Y. Zhang, X. F. Lin, J. W. Hu, D. Y. Wu,
Faraday Discussions2006, 132, 159
(21)Confocal microprobe Raman spectroscopy for investigating the electrochemical interface
B. Ren, F. M. Liu, X. F. Lin,Z. Q. Tian, Chin. J. Electrochem.2001, 7, 41
(22) Rh as a Ubiquitous Substrates for surface enhanced Raman spectroscopy
B. Ren, X. F. Lin,Z. Q. Tian, Chin. J. Electrochem.2001, 7, 55
(23)In situ Raman spectroscopic studies on the reduction of the surface oxides of rhodium at solid/liquid and solid/gasinterfaces
X. F. Lin,B. Ren, Y. Y. Liao, W.Y. Hu, Z. Q. Tian, Chin. J. Light Scattering2002, 14, 111.

发表教学论文
1、非化学专业物理化学课中的情境创设——以油气储运专业为例，林旭锋，王芳珠，杨国华，化学教育，2015年第18期。
授权发明专利：
1、林旭锋等，一种用于甘油加氢制正丙醇的双层组合催化剂，授权号：ZL .1。
2、林旭锋等，负载型镍催化剂的气相沉积制备方法，授权号：ZL 6.3。
3、林旭锋等，负载型铁催化剂的气相沉积制备方法，授权号：ZL 7.X。
4、林旭锋等，负载型钯催化剂的制备方法，授权号：ZL 5.7。
5、林旭锋等，负载型铂催化剂的铂颗粒稳定化处理方法，授权号：ZL 9.1。
6、林旭锋等，乙烷氧化脱氢制乙烯的装置及方法，授权号：ZL 2.6。

获奖情况：
科研成果奖励：
青岛西海岸新区科学技术奖自然科学奖三等奖，有机小分子增值转化的催化体系设计、制备与催化机理研究（编号：Z2015-3-1-1），1/2，2016.05；厅局级。
教学成果奖励：
基于物理化学混合教学模式的资源构建与教改实践，中国石油大学（华东）教学成果二等奖，5/7，2017.11；厅局级

获得荣誉：
2013.9，中国石油大学（华东）优秀教师；
2013.12，中国石油大学（华东）工会积极分子；
2010.12，中国石油大学（华东）大学生科技节优秀指导教师；
2010.1，中国石油大学（华东）化学化工学院优秀班主任。