徐磊磊


个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授




个人简介Personal Profile
姓名:徐磊磊
性别:男
职称:副教授
最高学历:博士
毕业院校:中国科学院兰州化学物理研究所
研究方向:二氧化碳资源化利用；有害VOCs催化消除；有害小分子催化消除；环境催化材料
邮箱:leileixu88@gmail.com



教育背景:
2008.09-2013.06 中国科学院兰州化学物理研究所，博士
2013.06-2013.08 新加坡国立大学苏州研究院，研究员
2013.08-2015.08 新加坡国立大学，Postdoctoral Research Fellow
2015.09-2017.09 韩国基础科学研究院，Research Fellow
2019.03-2020.03 阿卜杜拉国王科技大学，访问****

学术兼职:
Frontier in Chemistry (中科院SCI二区), Special issue "Advanced Metal Oxide Nanomaterials for Energy Conversion", Guest Editor

荣誉获奖:
1、第十八届全国稀土催化会议优秀论文奖，2011 年，中国稀土学会
2、第二十六届甘肃省青少年科技创新大赛一等奖（辅导），2011 年，甘肃省科协、甘肃省教育厅
3、中国科学院朱李月华优秀博士生奖学金，2013 年，中国科学院前沿科学与教育局
4、南京市第十二届自然科学优秀学术论文奖，2018 年，南京市自然科学优秀学术论文评审委员会

近期科研项目:
有序介孔限域的镍/钴基金属氧化物材料的构建及其催化甲烷二氧化碳重整反应性能研究，国家自然科学基金委，主持

迷你公告板:
本课题组长期从事温室气体CO2资源化利用、有害VOCs催化消除、有害小分子催化消除、环境催化新材料等领域的研究工作，环境与能源催化实验室具有固定床反应器（2套）、美国Perkins Elmer GC 680在线全自动进样色谱、天美GC7900在线全自动进样色谱、美国TILON LCD-200在线质谱、反应动力学评价系统（1套）等先进科研设备，并与中科院兰州化物所、新加坡国立大学、韩国科学技术院、阿卜杜拉国王科技大学、济南大学、山东理工大学、江苏大学、南京林业大学、中科院青岛能源所等国内外科研单位具有良好的合作关系。
实验室自2017年9月成立至今已经发表论文近30篇，与陈敏东教授联合培养研究生多名，实验室现有在读研究生11名（含博士生1名），本科生5名，其中2020级崔岩同学荣获博士入学一等奖学金（全院仅1人），2018级吕楚菲同学和吴限赟同学荣获2020年硕士研究生国家奖学金（全院共5人获奖），2017级崔岩同学荣获2019年硕士研究生国家奖学金（全院共5人获奖）并顺利保送博士研究生，2016级连鑫博同学成功考取兰州大学（985和双一流高校）博士研究生。
热烈欢迎具有环境、化学等专业背景的同学加入本课题组，一起共同学习进步！

近期主要论著:
本课题组长期从事温室气体二氧化碳资源化利用、有害VOCs催化消除、有害小分子催化消除、环境催化新材料等领域的研究工作，课题负责人先后在中科院兰州化物所羰基合成与选择氧化国家重点实验室攻读博士学位，并在新加坡国立大学化学系（NUS）、韩国基础科学研究院纳米材料与化学反应中心（韩国科学技术院化学系，KAIST）、阿卜杜拉国王科技大学催化中心（KAUST）等单位从事科学研究。
已在Applied Catalysis B: Environmental、ACS Catalysis、Fuel、ChemCatChem、Catalysis Science & Technology、Journal of CO2 Utilization、International Journal of Hydrogen Energy等环境、催化、能源化工等领域权威专业期刊上共发表SCI论文70余篇，已被引用2200余次，单篇引用超过200次的论文2篇， h因子为29，i10因子为44。
已发表部分论文与专利如下：
[1] F. Wang, K. Han, L. Xu, H. Yu, W. Shi, Ni/SiO2 Catalyst Prepared by Strong Electrostatic Adsorption for a Low-Temperature Methane Dry Reforming Reaction, Industrial & Engineering Chemistry Research (2021).
[2] Y. Shao, J. Wang, K. Sun, G. Gao, C. Li, L. Zhang, S. Zhang, L. Xu, G. Hu, X. Hu, Selective hydrogenation of furfural and its derivative over bimetallic NiFe-based catalysts: Understanding the synergy between Ni sites and Ni-Fe alloy, Renewable Energy (2021).
[3] Y. Shao, Q. Li, X. Dong, J. Wang, K. Sun, L. Zhang, S. Zhang, L. Xu, X. Yuan, X. Hu, Cooperation between hydrogenation and acidic sites in Cu-based catalyst for selective conversion of furfural to γ-valerolactone, Fuel 293 (2021) 120457.
[4] Z. Miao, J. Meng, M. Liang, Z. Li, Y. Zhao, F. Wang, L. Xu, J. Mu, S. Zhuo, J. Zhou, In-situ CVD synthesis of Ni@ N-CNTs/carbon paper electrode for electro-reduction of CO2, Carbon 172 (2021) 324-333.
[5] X. Li, L. Zhang, Q. Li, Z. Zhang, S. Zhang, Y. Li, S. Niu, M. Gholizadeh, L. Xu, X. Hu, Steam reforming of sugars: Roles of hydroxyl group and carbonyl group in coke formation, Fuel 292 (2021) 120282.
[6] X. Li, Y. Wang, H. Fan, Q. Liu, S. Zhang, G. Hu, L. Xu, X. Hu, Impacts of residence time on transformation of reaction intermediates and coking behaviors of acetic acid during steam reforming, Journal of the Energy Institute 95 (2021) 101-119.
[7] K. Han, W. Yu, L. Xu, Z. Deng, H. Yu, F. Wang, Reducing carbon deposition and enhancing reaction stability by ceria for methane dry reforming over Ni@ SiO2@ CeO2 catalyst, Fuel 291 (2021) 120182.
[8] Z. Gao, G. Gao, C. Li, H. Tian, Q. Xu, S. Zhang, L. Xu, X. Hu, Interaction of the reaction intermediates in co-reforming of acetic acid and ethanol impacts coke properties, Molecular Catalysis 504 (2021) 111461.
[9] Z. Zhang, X. Zhang, L. Zhang, J. Gao, Y. Shao, D. Dong, S. Zhang, Q. Liu, L. Xu, X. Hu, Impacts of alkali or alkaline earth metals addition on reaction intermediates formed in methanation of CO2 over cobalt catalysts, Journal of the Energy Institute 93(4) (2020) 1581-1596.
[10] Z. Zhang, Y. Sun, Y. Wang, K. Sun, Z. Gao, Q. Xu, S. Zhang, G. Hu, L. Xu, X. Hu, Steam reforming of acetic acid and guaiacol over Ni/Attapulgite catalyst: Tailoring pore structure of the catalyst with KOH activation for enhancing the resistivity towards coking, Molecular Catalysis 493 (2020) 111051.
[11] H. Yang, L. Xu, M. Chen, C. Lv, Y. Cui, X. Wen, C.-e. Wu, B. Yang, Z. Miao, X. Hu, Facilely fabricating highly dispersed Ni-based catalysts supported on mesoporous MFI nanosponge for CO2 methanation, Microporous and Mesoporous Materials 302 (2020) 110250.
[12] B. Yang, Q. Jin, Q. Huang, M. Chen, L. Xu, Y. Shen, H. Xu, S. Zhu, X. Li, Synergetic catalytic removal of chlorobenzene and NOx from waste incineration exhaust over MnNb0. 4Ce0. 2Ox catalysts: Performance and mechanism study, Journal of Rare Earths 38(11) (2020) 1178-1189.
[13] L. Xu, X. Wen, M. Chen, C. Lv, Y. Cui, X. Wu, C.-e. Wu, B. Yang, Z. Miao, X. Hu, Mesoporous Ce-Zr solid solutions supported Ni-based catalysts for low-temperature CO2 methanation by tuning the reaction intermediates, Fuel 282 (2020) 118813.
[14] X. Wu, L. Xu, M. Chen, C. Lv, X. Wen, Y. Cui, C.-e. Wu, B. Yang, Z. Miao, X. Hu, Recent Progresses in the Design and Fabrication of Highly Efficient Ni-Based Catalysts With Advanced Catalytic Activity and Enhanced Anti-coke Performance Toward CO2 Reforming of Methane, Frontiers in Chemistry 8 (2020).
[15] Z. Miao, Z. Li, M. Liang, J. Meng, Y. Zhao, L. Xu, J. Mu, J. Zhou, S. Zhuo, W. Si, Ordered mesoporous titanium phosphate material: A highly efficient, robust and reusable solid acid catalyst for acetalization of glycerol, Chemical Engineering Journal 381 (2020) 122594.
[16] C. Lv, L. Xu, M. Chen, Y. Cui, X. Wen, C.-e. Wu, B. Yang, F. Wang, Z. Miao, X. Hu, Constructing highly dispersed Ni based catalysts supported on fibrous silica nanosphere for low-temperature CO2 methanation, Fuel 278 (2020) 118333.
[17] C. Lv, L. Xu, M. Chen, Y. Cui, X. Wen, Y. Li, C.-e. Wu, B. Yang, Z. Miao, X. Hu, Recent progresses in constructing the highly efficient Ni based catalysts with advanced low-temperature activity toward CO2 methanation, Frontiers in chemistry 8 (2020) 269.
[18] C. Liang, L. Zhang, Y. Zheng, S. Zhang, Q. Liu, G. Gao, D. Dong, Y. Wang, L. Xu, X. Hu, Methanation of CO2 over nickel catalysts: Impacts of acidic/basic sites on formation of the reaction intermediates, Fuel 262 (2020) 116521.
[19] J. Li, X. Mei, L. Zhang, Z. Yu, Q. Liu, T. Wei, W. Wu, D. Dong, L. Xu, X. Hu, A comparative study of catalytic behaviors of Mn, Fe, Co, Ni, Cu and Zn–Based catalysts in steam reforming of methanol, acetic acid and acetone, International Journal of Hydrogen Energy 45(6) (2020) 3815-3832.
[20] C. Li, C. Zhang, G. Gao, M. Gholizadeh, S. Zhang, L. Xu, L. Zhang, Q. Li, X. Hu, Interaction of the volatiles from co-pyrolysis of pig manure with cellulose/glucose and their effects on char properties, Journal of Environmental Chemical Engineering 8(6) (2020) 104583.
[21] B. Han, L. Zhao, F. Wang, L. Xu, H. Yu, Y. Cui, J. Zhang, W. Shi, Effect of Calcination Temperature on the Performance of the Ni@ SiO2 Catalyst in Methane Dry Reforming, Industrial & Engineering Chemistry Research 59(30) (2020) 13370-13379.
[22] B. Han, F. Wang, L. Zhang, Y. Wang, W. Fan, L. Xu, H. Yu, Z. Li, Syngas production from methane steam reforming and dry reforming reactions over sintering-resistant Ni@ SiO 2 catalyst, Research on Chemical Intermediates 46(3) (2020) 1735-1748.
[23] Z. Zhang, Y. Tian, L. Zhang, S. Hu, J. Xiang, Y. Wang, L. Xu, Q. Liu, S. Zhang, X. Hu, Impacts of nickel loading on properties, catalytic behaviors of Ni/geAl2O3 catalysts and the reaction intermediates formed in methanation of CO2, international journal of hydrogen energy 44(9291) (2019) e9306.
[24] Z. Zhang, Y. Tian, L. Zhang, S. Hu, J. Xiang, Y. Wang, L. Xu, Q. Liu, S. Zhang, X. Hu, Impacts of nickel loading on properties, catalytic behaviors of Ni/γ–Al2O3 catalysts and the reaction intermediates formed in methanation of CO2, International Journal of Hydrogen Energy 44(18) (2019) 9291-9306.
[25] L. Zhang, F. Wang, J. Zhu, B. Han, W. Fan, L. Zhao, W. Cai, Z. Li, L. Xu, H. Yu, CO2 reforming with methane reaction over Ni@ SiO2 catalysts coupled by size effect and metal-support interaction, Fuel 256 (2019) 115954.
[26] B. Yang, Z. Li, Q. Huang, M. Chen, L. Xu, Y. Shen, S. Zhu, Synergetic removal of elemental mercury and NO over TiCe0. 25Sn0. 25Ox catalysts from flue gas: Performance and mechanism study, Chemical Engineering Journal 360 (2019) 990-1002.
[27] L. Xu, Y. Cui, M. Chen, X. Lian, B. Yang, C.-e. Wu, F. Wang, Effects of the fabrication strategy on the catalytic performances of Co–Ni bimetal ordered mesoporous catalysts toward CO 2 methanation, Sustainable Energy & Fuels 3(11) (2019) 3038-3049.
[28] F. Wang, Y. Wang, L. Zhang, J. Zhu, B. Han, W. Fan, L. Xu, H. Yu, W. Cai, Z. Li, Performance enhancement of methane dry reforming reaction for syngas production over Ir/Ce0. 9La0. 1O2-nanorods catalysts, Catalysis Today (2019).
[29] X. Lian, L. Xu, M. Chen, C.-e. Wu, W. Li, B. Huang, Y. Cui, Carbon dioxide captured by metal organic frameworks and its subsequent resource utilization strategy: a review and prospect, Journal of nanoscience and nanotechnology 19(6) (2019) 3059-3078.
[30] Y. Cui, L. Xu, M. Chen, C. Lv, X. Lian, C.-e. Wu, B. Yang, Z. Miao, F. Wang, X. Hu, CO oxidation over metal oxide (La2O3, Fe2O3, PrO2, Sm2O3, and MnO2) doped CuO-based catalysts supported on mesoporous Ce0. 8Zr0. 2O2 with intensified low-temperature activity, Catalysts 9(9) (2019) 724.
[31] Y. Cui, L. Xu, M. Chen, X. Lian, C.-e. Wu, B. Yang, Z. Miao, F. Wang, X. Hu, Facilely fabricating mesoporous nanocrystalline Ce–Zr solid solution supported CuO-based catalysts with advanced low-temperature activity toward CO oxidation, Catalysis Science & Technology 9(20) (2019) 5605-5625.
[32] Y. Cui, X. Lian, L. Xu, M. Chen, B. Yang, C.-e. Wu, W. Li, B. Huang, X. Hu, Designing and fabricating ordered mesoporous metal oxides for CO2 catalytic conversion: a review and prospect, Materials 12(2) (2019) 276.
[33] L. Xu, X. Lian, M. Chen, Y. Cui, F. Wang, W. Li, B. Huang, CO2 methanation over CoNi bimetal-doped ordered mesoporous Al2O3 catalysts with enhanced low-temperature activities, International Journal of Hydrogen Energy 43(36) (2018) 17172-17184.
[34] F. Wang, B. Han, L. Zhang, L. Xu, H. Yu, W. Shi, CO2 reforming with methane over small-sized Ni@ SiO2 catalysts with unique features of sintering-free and low carbon, Applied Catalysis B: Environmental 235 (2018) 26-35.
[35] L. Xu, H. Yang, M. Chen, F. Wang, D. Nie, L. Qi, X. Lian, H. Chen, M. Wu, CO2 methanation over Ca doped ordered mesoporous Ni-Al composite oxide catalysts: The promoting effect of basic modifier, Journal of CO2 Utilization 21 (2017) 200-210.
[36] L. Xu, F. Wang, M. Chen, H. Yang, D. Nie, L. Qi, X. Lian, Alkaline-promoted Ni based ordered mesoporous catalysts with enhanced low-temperature catalytic activity toward CO 2 methanation, RSC advances 7(30) (2017) 18199-18210.
[37] L. Xu, F. Wang, M. Chen, D. Nie, X. Lian, Z. Lu, H. Chen, K. Zhang, P. Ge, CO2 methanation over rare earth doped Ni based mesoporous catalysts with intensified low-temperature activity, International Journal of Hydrogen Energy 42(23) (2017) 15523-15539.
[38] L. Xu, F. Wang, M. Chen, X. Fan, H. Yang, D. Nie, L. Qi, Alkaline-promoted Co-Ni bimetal ordered mesoporous catalysts with enhanced coke-resistant performance toward CO2 reforming of CH4, Journal of CO2 Utilization 18 (2017) 1-14.
[39] F. Wang, L. Zhang, L. Xu, Z. Deng, W. Shi, Low temperature CO oxidation and CH4 combustion over Co3O4 nanosheets, Fuel 203 (2017) 419-429.
[40] F. Wang, L. Xu, J. Yang, J. Zhang, L. Zhang, H. Li, Y. Zhao, H.X. Li, K. Wu, G.Q. Xu, Enhanced catalytic performance of Ir catalysts supported on ceria-based solid solutions for methane dry reforming reaction, Catalysis Today 281 (2017) 295-303.
[41] F. Wang, L. Xu, W. Shi, J. Zhang, K. Wu, Y. Zhao, H. Li, H.X. Li, G.Q. Xu, W. Chen, Thermally stable Ir/Ce 0.9 La 0.1 O 2 catalyst for high temperature methane dry reforming reaction, Nano Research 10(2) (2017) 364-380.
[42] J. Cho, L. Xu, C. Jo, R. Ryoo, Highly monodisperse supported metal nanoparticles by basic ammonium functionalization of mesopore walls for industrially relevant catalysis, Chemical Communications 53(27) (2017) 3810-3813.
[43] K. Yuan, J.-Q. Zhong, X. Zhou, L. Xu, S.L. Bergman, K. Wu, G.Q. Xu, S.L. Bernasek, H.X. Li, W. Chen, Dynamic oxygen on surface: catalytic intermediate and coking barrier in the modeled CO2 reforming of CH4 on Ni (111), ACS Catalysis 6(7) (2016) 4330-4339.
[44] L. Xu, X. Zhang, M. Chen, L. Qi, D. Nie, Y. Ma, Facilely fabricating Mg, Ca modified Co based ordered mesoporous catalysts for CO2 reforming of CH4: The effects of basic modifiers, International Journal of Hydrogen Energy 41(39) (2016) 17348-17360.
[45] L. Xu, F. Wang, M. Chen, J. Zhang, K. Yuan, L. Wang, K. Wu, G. Xu, W. Chen, Carbon dioxide reforming of methane over cobalt‐nickel bimetal‐doped ordered mesoporous alumina catalysts with advanced catalytic performances, ChemCatChem 8(15) (2016) 2536-2548.
[46] L. Xu, F. Wang, M. Chen, J. Zhang, K. Yuan, L. Wang, K. Wu, G. Xu, W. Chen, CO 2 methanation over a Ni based ordered mesoporous catalyst for the production of synthetic natural gas, RSC advances 6(34) (2016) 28489-28499.
[47] Y. Wang, F. Pan, W. Dong, L. Xu, K. Wu, G. Xu, W. Chen, Recyclable silver-decorated magnetic titania nanocomposite with enhanced visible-light photocatalytic activity, Applied Catalysis B: Environmental 189 (2016) 192-198.
[48] F. Wang, L. Xu, J. Zhang, Y. Zhao, H. Li, H.X. Li, K. Wu, G.Q. Xu, W. Chen, Tuning the metal-support interaction in catalysts for highly efficient methane dry reforming reaction, Applied Catalysis B: Environmental 180 (2016) 511-520.
[49] F. Wang, L. Xu, W. Shi, Syngas production from CO2 reforming with methane over core-shell Ni@ SiO2 catalysts, Journal of CO2 Utilization 16 (2016) 318-327.
[50] J.L. Zhang, Z. Wang, J.Q. Zhong, K.D. Yuan, Q. Shen, L.L. Xu, T.C. Niu, C.D. Gu, C.A. Wright, A. Tadich, Single-molecule imaging of activated nitrogen adsorption on individual manganese phthalocyanine, Nano letters 15(5) (2015) 3181-3188.
[51] J. Zhang, L. Wang, L. Xu, X. Ge, X. Zhao, M. Lai, Z. Liu, W. Chen, Porous cobalt–manganese oxide nanocubes derived from metal organic frameworks as a cathode catalyst for rechargeable Li–O 2 batteries, Nanoscale 7(2) (2015) 720-726.
[52] J. Zhang, Y. Luan, Z. Lyu, L. Wang, L. Xu, K. Yuan, F. Pan, M. Lai, Z. Liu, W. Chen, Synthesis of hierarchical porous δ-MnO 2 nanoboxes as an efficient catalyst for rechargeable Li–O 2 batteries, Nanoscale 7(36) (2015) 14881-14888.
[53] L. Xu, J. Zhang, F. Wang, K. Yuan, L. Wang, K. Wu, G. Xu, W. Chen, One-step synthesis of ordered mesoporous CoAl 2 O 4 spinel-based metal oxides for CO 2 reforming of CH 4, RSC Advances 5(60) (2015) 48256-48268.
[54] L.J. Wang, J. Zhang, X. Zhao, L.L. Xu, Z.Y. Lyu, M. Lai, W. Chen, Palladium nanoparticle functionalized graphene nanosheets for Li–O 2 batteries: enhanced performance by tailoring the morphology of the discharge product, RSC advances 5(90) (2015) 73451-73456.
[55] W. Dong, F. Pan, L. Xu, M. Zheng, C.H. Sow, K. Wu, G.Q. Xu, W. Chen, Facile synthesis of CdS@ TiO2 core–shell nanorods with controllable shell thickness and enhanced photocatalytic activity under visible light irradiation, Applied Surface Science 349 (2015) 279-286.
[56] L. Xu, Z. Miao, H. Song, L. Chou, CO2 reforming of CH4 over rare earth elements functionalized mesoporous NieLn (Ln [Ce, La, Sm, Pr) eAleO composite oxides, international journal of hydrogen energy 39(3253) (2014) e3268.
[57] L. Xu, Z. Miao, H. Song, L. Chou, CO2 reforming of CH4 over rare earth elements functionalized mesoporous Ni–Ln (Ln= Ce, La, Sm, Pr)–Al–O composite oxides, International journal of hydrogen energy 39(7) (2014) 3253-3268.
[58] L. Xu, Z. Miao, H. Song, W. Chen, L. Chou, Significant roles of mesostructure and basic modifier for ordered mesoporous Ni/CaO–Al 2 O 3 catalyst towards CO 2 reforming of CH 4, Catalysis Science & Technology 4(6) (2014) 1759-1770.
[59] Z. Miao, H. Song, H. Zhao, L. Xu, L. Chou, One-pot synthesis of mesoporous ZrPW solid acid catalyst for liquid phase benzylation of anisole, Catalysis Science & Technology 4(3) (2014) 838-850.
[60] H. Zhao, H. Song, L. Xu, L. Chou, Isobutane dehydrogenation over the mesoporous Cr2O3/Al2O3 catalysts synthesized from a metal-organic framework MIL-101, Applied Catalysis A: General 456 (2013) 188-196.
[61] L. Xu, Z. Wang, H. Song, L. Chou, Catalytic dehydrogenation of isobutane over ordered mesoporous Cr2O3–Al2O3 composite oxides, Catalysis Communications 35 (2013) 76-81.
[62] L. Xu, H. Song, L. Chou, Ordered mesoporous MgO–Al2O3 composite oxides supported Ni based catalysts for CO2 reforming of CH4: Effects of basic modifier and mesopore structure, International journal of hydrogen energy 38(18) (2013) 7307-7325.
[63] Z. Miao, L. Xu, H. Song, H. Zhao, L. Chou, One-pot synthesis of ordered mesoporous zirconium oxophosphate with high thermostability and acidic properties, Catalysis Science & Technology 3(8) (2013) 1942-1954.
[64] L. Xu, H. Zhao, H. Song, L. Chou, Ordered mesoporous alumina supported nickel based catalysts for carbon dioxide reforming of methane, International journal of hydrogen energy 37(9) (2012) 7497-7511.
[65] L. Xu, H. Song, L. Chou, Facile synthesis of nano-crystalline alpha-alumina at low temperature via an absolute ethanol sol–gel strategy, Materials Chemistry and Physics 132(2-3) (2012) 1071-1076.
[66] L. Xu, H. Song, L. Chou, Mesoporous nanocrystalline ceria–zirconia solid solutions supported nickel based catalysts for CO2 reforming of CH4, International journal of hydrogen energy 37(23) (2012) 18001-18020.
[67] L. Xu, H. Song, L. Chou, One-pot synthesis of ordered mesoporous NiO–CaO–Al2O3 composite oxides for catalyzing CO2 reforming of CH4, Acs Catalysis 2(7) (2012) 1331-1342.
[68] L. Xu, H. Song, L. Chou, Carbon dioxide reforming of methane over ordered mesoporous NiO–Al 2 O 3 composite oxides, Catalysis Science & Technology 1(6) (2011) 1032-1042.
[69] L. Xu, H. Song, L. Chou, Carbon dioxide reforming of methane over ordered mesoporous NiO–MgO–Al2O3 composite oxides, Applied Catalysis B: Environmental 108 (2011) 177-190.

发明专利成果:
[1] Lingjun Chou*, Leilei Xu, Huanling Song, Jian Yang, Jun Zhao, A method for preparing alpha-alumina powder (Chinese), Patent No. CN2.7
[2] Chen Wei, Leilei Xu, Guoqin Xu, Kai Wu, Ordered Mesoporous CoAl2O4 Spinel Based Metal Oxides for CO2 Reforming of CH4 (ILO Ref: 14413N), filed (equal contribution).



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徐磊磊


个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授






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徐磊磊


个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授






研究领域 当前位置： 中文主页 >> 科学研究 >> 研究领域

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徐磊磊


个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授






论文成果 当前位置： 中文主页 >> 科学研究 >> 论文成果
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---

徐磊磊


个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授






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个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授






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徐磊磊


个人信息Personal Information 副教授
教师拼音名称：XU LEILEI
所在单位：环境科学与工程学院
性别：男
联系方式：leileixu88@gmail.com
职称：副教授






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