本科生

《能源化学》、《无机合成化学》

硕士生

《科学研究方法讲座》

博士生

《无机合成方法》

谢在来教授2009年赴德国坡茨坦大学（Potsdam Univ.）和马克斯-普朗克胶体与界面研究所（Colloids and Interfaces）攻读超分子化学博士学位，博士毕业后先后在德国马克斯-普朗克学会弗里茨·哈伯（Fritz-Haber-Institute）研究所、马克斯-普朗克化学能源转化（Chemical Energy Conversion）研究所从事博士后研究工作，2015年回到福州大学任教。近几年在碳催化、非金属材料合成、核碱基自组装和硼碳氮材料等方面做出了大量的研究。针对现有商业化烃类脱氢催化剂成本高、环境不友好等问题，侧重于发展可替代贵金属和金属氧化物类催化剂的非金属催化剂，并取得了多个特色鲜明的研究成果：1）将超分子自组装方法应用到碳基催化材料的设计与合成上，成功制备得到了具有高密度羰基活性位、抗氧化能力强的有序介孔纳米碳催化材料；2）经过多年构效机制的探究，首次揭示了硼基催化材料的活性中心来源，并以此为基础开发出硼碳氮团簇类型的高效氧化脱氢催化剂。

谢在来教授近年来以第一作者或通讯作者在包括Sci. Adv.、Nat. Commun.、Angew. Chem. Int. Ed.（3）、Chem、Adv. Mater.、Adv. Funct. Mater.等权威刊物上发表文章120余篇，参撰中英文专著 2部，获授权发明专利 7件。此外，谢在来教授还先后主持中组部国家万人计划青年拔尖人才项目、福建省闽江学者科研启动基金、福建省首批雏鹰计划青年拔尖人才项目、福建省自然科学基金杰出青年项目、国家自然科学基金面上项目（3项）和多项国家重点实验室课题项目。

[1] 福建省化学会副秘书长、常务理事

[2] 先进碳基功能材料福建省高校重点实验室主任

[3] 福建省消防标准化技术委员会副主任委员

[4] 福州大学材料与化工专业学位研究生培养指导委员会委员

[5] 《Carbon Future》、《Green Carbon》、《Catalysts》等期刊编委

[6] 中国化学会高级会员

[1] 国家自然科学基金面上项目（B020102）：鸟嘌呤晶体衍生高氮掺杂空心碳棱柱体的制备与催化机制研究，22372039，（2024.01-2027.12），主持；

[2] 国家自然科学基金面上项目（B020102）：核碱基自组装导向纳米碳催化剂的合成与烷烃氧化脱氢反应性能调控，22072018，（2021.01-2024.12），主持；

[3] 国家自然科学基金面上项目（B03）：基于PMMA-SiO2含染料离子凝胶薄膜光功能材料的制备和性能研究，21571035，（2016.01-2019.12），主持；

[4] 中组部国家“万人计划”青年拔尖人才项目：（2022.01-2024.12），主持；

[5] 福建省首批“雏鹰计划”青年拔尖人才项目：00387074，（2020.12-2025.12），主持；

[6] 福建省自然科学基金杰青项目：基于硼碳氮材料的纳米催化剂合成及应用研究，2021J06010，（2021.11-2024.11），主持；

[7] 福建省“闽江学者”特聘教授：多孔碳材料制备和催化，510140，（2015.04-2018.03），主持；

[8] 煤炭高效利用与绿色化工国家重点实验室：铑基催化剂用于煤经合成气转化制备低碳醇，2020-KF-16，（2020.01-2022.12），主持；

[9] 固体表面物理化学国家重点实验室开放基金：氮掺杂纳米碳负载金属铑基催化剂的设计以及用于合成气转化制备低碳醇的研究，201518，（2016.01-2018.12），主持；

[10] 能源与环境光催化国家重点实验室开放课题：碳量子点基光催化剂的可控制备及其在太阳燃料合成中的应用，SKLPEE-20190019，（2020.01-2022.12），主持；

[11] 结构化学国家重点实验室开放基金：Rh基催化剂用于合成气转化制备低碳醇的催化机制研究，20170009（2017.01-2019.12），

[77] Zailai Xie et.al.*, A Team for the Development of Next-Generation Metal-Free Catalysis, Angew. Chem. Int. Ed., 2023, e202312696 (Team profile).

[76] Guangming Wang, Shunhua Chen, Qiwei Duan, Fenfei Wei, Sen Lin*, and Zailai Xie*, Surface Chemistry and Catalytic Reactivity of Borocarbonitride in Oxidative Dehydrogenation of Propane, Angew. Chem. Int. Ed., 2023, e202307470 (HOT paper).

[75] S. C. Wu, M. Zhao, Z. J. Xia, J. Y. Diao, Z. L. Xie*, Insights into the degradation of organic pollutants via peroxymonosulfate activation over highly adsorptive carbon, New J. Chem., 2023, 47, 12080-12084.

[74] X. F. Zhang, Y. B. Lu, Y. Y. Han, R. P. Feng, Z. L. Xie*, Unravelling the role of boron dopant in borocarbonitirde catalytic dehydrogenation reaction, J. Energy Chem.,2023, 85, 137-143.

[73] S. Chen, M. Xia, X. F. Zhang, L. S. Pei, Z. J. Li, X. Ge, M. J. Lin, W. Zhang*, Z. L. Xie*, Guanosine-Derived Atomically Dispersed Cu-N3-C Sites for Efficient Electroreduction of Carbon Dioxide, J. Colloid. Interf. Sci., 2023, 646, 863-871.

[72] X. F. Zhang, T. Lei, M. Xia, Q. H. Wei*, Z. L. Xie*, Core-shell Mo2C@NC/Mo2C hollow microspheres as highly efficient electrocatalysts for the hydrogen evolution reaction, Dalton Trans., 2023, 52, 6267-6272.

[71] F. F. Yang, Z. L. Xie, X. K. Huang, X. Y. Yin, W. F. Zhang, Y. K. Huang, D. J. Zhang*, Bi2S3 nanorods grown on multiwalled carbon nanotubes as highly active catalysts for CO2 electroreduction to formate, Phys. Chem. Chem. Phys., 2023,25, 9198-9207.

[70] Y. Hou, M. Xia, Y. Y. Han, X. F. Zhang, Y. B. Lu, Q. H. Yang, Z. L. Xie*, Folic Acid-Derived Low-dimensional carbons for efficient oxidative dehydrogenation of ethylbenzene, J. Colloid. Interf. Sci., 2023, 638, 291-299.

[69] P. Wang, M. Yang, H. F. Liao, K. Y. Xu, X. P. Zong, Z. L. Xie, H. B. Zhao, Y. J. Xu, H. Yang, Y. Y. Gan, Y. Fang, L. Z. Wu, Y. Tang, L. Tan*, Cell. Rep. Phys. Sci., 2023, 2, 101311.

[68] M. Xia, S. C. Li, Z. L. Xie*, Self-assembly of guanosine into carbon-based multilayer materials, Chem. Commun., 2023, 59, 2783-2786.

[67] P. Wang, H. F. Liao, H. Yang, Q. Lv, Y. R. Li, L. Z. Wu, Y. Tang, Z. L. Xie, L. Tan*, Constructing PtCe cluster catalysts by regulating metal-support interaction via Al in zeolite for propane dehydrogenation, Chem. Eng. Sci., 2023, 269, 118450.

[69] X. D. Ding, Y. X. Huang, D. Y. Chen, Z. L. Xie*, CeO2 nanoparticles-decorated CoP nanocubes for accelerating alkaline electrocatalytic oxygen evolution reaction, Particuology, 2023, 81, 38-44.

[68] X. D. Ding, J. Yu, W. Q. Huang, D. Y. Chen*, W. Lin*, Zailai Xie*, Modulation of the interfacial charge density on Fe2P-CoP by coupling CeO2 for accelerating alkaline electrocatalytic hydrogen evolution reaction and overall water splitting, Chem. Eng. J., 2023, 451, 138550.

[67] S. C. Li, Y. L. Ke, X. F. Zhang, S. C. Wu, Y. Q. Chen*, Z. L. Xie*, Guanine-derived nitrogen-doped carbon nanosheets for selective oxidation of benzyl alcohol. Diam. Relat. Mater., 2023, 132, 109642.

2022

[66] X. Y. Huang, X. H. Zeng, X. F. Zhang*, Z. L. Xie*, Carbon-based frustrated Lewis pairs mediate hydrogenation. Phys. Chem. Chem. Phys., 2022, 24, 28895-28902.

[65] X. D. Ding, L. S. Pei, Y. X. Huang, D. Y. Chen*, Z. L. Xie*, Hollow NiCoP Nanoprisms Derived from Prussian Blue Analogues as Bifunctional Electrocatalysts for Urea-Assisted Hydrogen Production in Alkaline Media, Small, 2022, 22, 2205547.

[64] M. Xia, X. F. Zhang, Z. L. Xie*, New Family of Hydrothermal Carbons with Super-High Surface Areas Derived from Nucleosides for Oxygen Reduction, ACS Sustainable Chem. Eng., 2022, 10, 14330-14342.

[63] B. B. Huang, Y. X. Li, X. Guan, Zailai Xie*, Nucleobases-derived carbon materials: Synthesis and application in heterogeneous catalysis, FlatChem, 2022, 35, 100415.

[62] X. F. Zhang, X. Y Dai, K.-H. Wu, B. J. Su, J. M. Chen, W. Qi* and Z. L. Xie*, A Generalized Approach to Adjust the Catalytic Activity of Borocarbonitride for Alkane Oxidative Dehydrogenation Reactions, J. Catal., 2022, 405, 105-115.

[61] L. Wang, P. W. Cai, Z. Z. Liu, and Z. L. Xie* and Y. X. Fang*, Role of carbon quantum dots on Nickel titanate to promote water oxidation reaction under visible light illumination, J. Colloid Interface Sci., 2022, 607, 203-209.

[60] S. C. Li, X. F. Zhang, X. Y. Huang, and Z. L. Xie*, Identification of Active Sites of B/N co-Doped Nanocarbons in Selective Oxidation of Benzyl Alcohol, J. Colloid Interface Sci.,2022, 608, 2801-2808.

2021

[59]S. C. Wu*, L. H. Yu*, G. D. Wen,Z. L. Xie, and Y. M. Lin*，Recent progress of carbon-based metal-free materials in thermal-driven catalysis,J. Energy Chem., 2021, 58, 318-315.

[58] G. M. Wang, Y. Yan, X. F. Zhang, X. H. Gao and Z. L. Xie*，Three-dimensional porous hexagonal boron nitride fibers as metal-free catalysts with enhanced catalytic activity for oxidative dehydrogenation of propane,Ind. Eng. Chem. Res.2021, 12, in press.

[57] Z. S. Luo, Q. Wan, Z. Y. Yu,Z. L. Xie*, and X. C. Wang*,Photo-fluorination of nanodiamonds catalyzing oxidative dehydrogenation reaction of ethylbenzene,Nat. Commun., 2021, 12: 6542.

[56] Q. Wu, J. Liang,Z. L. Xie, Y.- B. Huang*, and R. Cao*,Spatial Sites Separation Strategy to Fabricate Atomically Isolated Nickel Catalysts for Efficient CO2Electroreduction,ACS Mater. Lett., 2021, 3, 454-461.

[55] J. N. Dong, X. N. Zhang, X. L. Dong, K. H. Ng,Z. L. Xie,I-W. P. Chen, Y. H. Ng, J. Y. Huang, and Y. K. Lai*, Coupled porosity and heterojunction engineering: MOF-derived porous Co3O4embedded on TiO2 nanotube arrays for water remediation,Chemosphere, 2021, 274, 129799.

[54] G. M. Wang, X. F. Zhang, Y. Yan, X. Huang andZ. L. Xie*, New insight into structural transformations of borocarbonitride in oxidative dehydrogenation of propane,Appl. Catal. A: Gen,2021, 628, 118402.

[53] Y. C. Liu, H. T. Huang, X. D. Ding, B. B. Huang, andZ. L. Xie*, Boosting the HER electrocatalytic activity over RuCu-supported carbon nanosheets as efficient pH-independent catalysts,FlatChem, 2021, 30, 100302.

[52] X. D. Ding, H. T. Huang, Q. Wang, Y. X. Fang, S. Lin, D. Y. Chen* and andZ. L. Xie*, Self-template synthesis of hollow Fe-doped CoP prisms with enhanced oxygen evolution reaction activity,J. Energy Chem., 2021, 62, 415-422.

[51] H. Luo, J. H. Liu, Y. Q. Chen*, andZ. L. Xie*, Microcrystalline cellulose derived-hierarchically porous nanocarbons via a template-free method for high performance supercapacitors,Diam. Relat. Mater., 2021, 117, 108462.

[50] M. Xia, H. T. Huang, X. F. Zhang, Q.-H. Wei andZ. L. Xie*, Single-atomic cobalt fused biomolecule-derived nitrogen-doped carbon nanosheets for selective oxidation reaction,Phys. Chem. Chem. Phys., 2021, 23, 14276-14283.

[49] Y. Chen, Y. Y. Li, B. S. Wang, M. J. Wang,Z. L. Xie*, D. Y. Chen*, Fluorinated poly(fluorenyl ether)s with linear multi-cationic side chains for vanadium redox flow batteries,Sci. China Mater.2021, 2, 349-361.

[48] B. B.Huang, Y. C. Liu, andZ. L. Xie*, Two dimensional nanocarbons from biomass and biological molecules: synthetic strategies and energy related applications,J. Energy Chem., 2021, 54, 795-814..

2020

[47] J. -D. Yi, R. K. Xie,Z. L. Xie,G.- L. Chai*, T. F. Liu, R. P. Chen, Y.- B. Huang, and R. Cao*, Highly Selective CO2 Electroreduction to CH4 by In Situ Generated Cu2O Single-Type Sites on Conductive MOF: Stabilizing Key Intermediates with Hydrogen Bond,Angew. Chem. Int. Ed.,2020, 52, 23641-23648.

[46] X. F. Zhang, P. Q. Yan, J. K. Xu, F., Li, F., Herold, B. J. M. Etzold, P. Wang, D. S. Su, S., Lin*, W. Qi* and Z. L. Xie*, Methanol conversion on borocarbonitride catalysts: identification and quantification of active sites,Sci. Adv.,2020, 6, eaba5778.

[45] L. Xiong, Y. F. Hu, Z. G Zheng,Z. L. Xie*, D. Y. Chen*,Chloromethylation and Quaternization of Poly(aryl ether ketone sulfone)s with Clustered Electron-rich Phenyl Groups for Anion Exchange Membranes,Chinese J. Polym. Sci.2020, 38, 278-287.

[44] G. M. Wang, P. Wang, X. F. Zhang, Q. H. Wei, S. C. Wu* and Z. L. Xie*, Nucleobase Derived Boron and Nitrogen co-doped Carbon Nanosheet as Efficient Catalyst for Selective Oxidation and Reduction Reactions,Nanoscale,2020, 12,7797-7803.

[43] K. -H. Wu, D. Wang, X. Y. Lu, X. F. Zhang,Z. L. Xie*,Y. F. Liu, D. S. Su, W. Qi*, S. J. Guo*, Highly Selective Hydrogen Peroxide Electrosynthesis on Carbon: In-Situ Interface Engineering with Surfactants,CHEM,2020, 6, 1443-1458.

.[42] K. Xu, Y. Y. Yue, X. J. Bao,Z. L. Xie,H. B. Zhu*, Propane Dehydrogenation over Pt Clusters Localized at the Sn Single-Site in Zeolite Framework,ACS Catal.,2020, 10, 1, 818-828.

[41] X. Hu, Y. C. Liu, H. T. Huang, G. L. Chai* andZ. L. Xie*,Template-free Synthesis of Graphene-like Carbons as Efficient Carbocatalysts for Selective Oxidation of Alkanes,Green Chem.2020,22, 1291-1300.

[40] Y. C. Liu, B. B. Huang, Q. H. Wei*, andZ. L. Xie*,One-step synthesis of N, P-codoped carbon nanosheets encapsulated CoP particles for highly efficient oxygen evolution reaction,Front. Chem.2020, 7:805.

[39] B. B. Huang, Y. C. Liu, M. Xia, J. G. Qiu, andZ. L. Xie*, Building microspheres-nanosheets structure in N-doped carbon to improve their performance in oxygen reduction reaction and vanadium redox flow battery,Sustain. Energy & Fuel, 2020, 4, 559-570.

[38] J. G. Qiu, B. B. Huang, Y. C. Liu, D. Chen* andZ. L. Xie*, Glucose-derived hydrothermal carbons as energy storage booster for vanadium redox flow batteries,J. Energy Chem., 2020, 45, 31-39.

[37] B. B. Huang, Y. C. Liu, Q. G, Y. X. F, M. M. Titirici, X. C. Wang andZ. L. Xie*, Porous carbon nanosheets from biological nucleobase precursor as efficient pH-independent oxygen reduction electrocatalyst,Carbon, 2020, 156, 179-186.

[36] L. Zhou, J. Zhu, M. Lin, J. Xu,Z. L. Xie*,,and D. Chen*, Tetra-alkylsulfonate functionalized poly(aryl ether) membranes with nanosized hydrophilic channels for efficient proton conduction,J. Energy Chem.,2020, 40, 57-64.

2019

[35] C. Liu, X. Hu, B. B. Huang, andZ. L. Xie*, Surface engineering of Rh catalysts with N/S co-doped carbon nanosheets towards high performance hydrogen evolution from seawater,ACS Sustain. Chem. & Eng.2019, 23, 18835-18843.

[34] B. B. Huang, Y. C. Liu, Q. H. Wei andZ. L. Xie*, Three-dimensional mesoporous graphene-like carbons derived from a biomolecule exhibiting high-performance oxygen reduction activity, Sustain.Sustain. Energy & Fuel, 2019, 3, 2809-2818.

[33] X. Hu, Y. Chen, B. Huang, Y. Liu, H. Huang andZ. L. Xie*, Pd supported N/S co-doped graphene-like carbons boost quinoline hydrogenation activity,ACS Sustain. Chem. & Eng.2019, 7, 11369-11376.

[32] J. Q. Zheng, D. X. Sun, B. B. Huang, Y. C. Liu, andZ. L. Xie*, Mesoporous Carbons Derived from Pyrolysis of Organosilica-Based Ionogels for Oxygen Reduction Reaction,Chemistryselect,2019, 4, 13828-13834.

[31] B. B. Huang, M. Xia, Q. G. Qiu andZ. L. Xie*, Biomass derived graphene‐like carbons for electrocatalytic oxygen reduction reaction,ChemNanoMat,2019, 5, 682-689.

[30] X. D. Ding, S. Lei, C. F. Du*,Z. L. Xie, J. R. Li*, X. Y. Huang, Small-sized CuS nanoparticles/N, S co-doped rGO composites as the anode materials for high-performance lithium-ion batteries,Adv. Mater. Interfaces,2019, 6, 201900038.

[29] D. Wang, W. Liu,Z. L. Xie, S, Tian, D, Su, Wei Qi*, Oxidative dehydrogenation of ethyl lactate over nanocarbon catalysts: Effect of oxygen functionalities and defects.Catal. Today,2019, in press.

[28] Y. C. Liu, B. Huang, and Z. L. Xie*, Surfactant-assisted hydrothermal synthesis of nitrogen doped Mo2C@C composites as highly efficient electrocatalysts for hydrogen evolution reaction.Int. J. Hydrogen Energy,2019,44, 3702-3710.

[27] B. Huang, X. Hu, Y. C. Liu, W. Qi and Z. L. Xie*, Biomolecule-derived N/S co-doped CNT-graphene hybrids exhibiting excellent electrochemical activities.J. Power Source,2019, 413, 408-417.

[26] Y. C. Liu, B. Huang, X. Huang* and Z. L. Xie*, In-situ fabrication of nitrogen-doped carbon nanosheets containing highly dispersed single iron atoms for oxygen reduction reaction.J. Power Source,2019, 412, 125-133.

2018

[25] B. B. Huang, Y. C. Liu, X. Huang* and Z. L. Xie*, Multiple heteroatom-doped few-layer carbons for the electrochemical oxygen reduction reaction.J. Mater. Chem. A, 2018, 6, 22277-22286.

[24] P. Wang, L. Tao, H. Luo, D. Chen* and Z. L. Xie*, Organosilica-based ionogel derived nitrogen-doped microporous carbons for high performance supercapacitor electrodes.Inorg. Chem. Front.2018, 5, 3091-3098.

[23] P. Yan,Z. L. Xie,* S. Tian, F. Li, D. Wang, D. S. Su* and W. Qi*, Hydration of phenylacetylene on sulfonated carbon materials: active site and intrinsic catalytic activity.RSC Adv.2018, 67, 38150-38156.

[22] X. Liu*, S. Zou, K. Liu, C. Lv, Z. Wu, Y. Yin, T. Liang,Z. L.Xie, Highly compressible three-dimensional graphene hydrogel for foldable all-solid-state supercapacitor.J. Power Source,2018, 384, 214-222.

[21] D. Wu, Y. Liu, Y. Wu, B. Tan,Z. L. Xie*, Microporous carbons derived from organosilica-containing carbon dots with outstanding supercapacitance.Dalton Trans.,2018, 17, 5961-5967.

[20]B. Tan, H. LuoZ. L.Xie*, Formation of N-rich Hierarchically Porous Carbon via Direct Growth ZIF-8 on C3N4 Nanosheet with Enhancing Electrochemical Performance.Chemistryselect,2018, 23, 6440-6449.

[19] Z. F. Wu, B. Tan, W. Ma, W.-W. Xiong,Z. L.Xie* and X.-Y. Huang*, Mg2+ incorporated Co-based MOF precursors for hierarchical CNTs-containing porous carbons with ORR activity.Dalton Trans.,2018, 47, 2810-2819.

[18] Y. C. Liu, B. B. Huang andZ. L. Xie*, Hydrothermal Synthesis of Core-Shell MoO2/α-Mo2C Heterojunction as High Performance Electrocatalyst for Hydrogen Evolution Reaction.Appl. Surf. Sci.2018, 427, 693-701.

2017

[17] B.B. Huang, Y. C. Liu, andZ. L. Xie*, Biomass derived 2D carbons via hydrothermal carbonization method as efficient bifunctional ORR/HER electrocatalysts.J. Mater. Chem. A,2017, 5, 23481-23488 (HOT paper, Front cover).

[16] B. Tan, Z. F. Wu, andZ. L.Xie*, Fine Decoration of Carbon Nanotubes with Metal Organic Frameworks for Enhanced Performance in Supercapacitance and Oxygen Reduction Reaction.Sci. Bull.2017, 62, 1132-1141.

[15] F. S.Guo, P. J. Yang, Z. M. Pan, X. -N. Cao,Z. L. Xie*, and X. C. Wang*, Carbon-Doped BN Nanosheets for the Oxidative Dehydrogenation of Ethylbenzene.Angew. Chem. Int. Ed.,2017, 56, 8231-8235.

[14] Y. C. Liu, B. B. Huang, X. X. Lin andZ. L.Xie*, Biomass-Derived Hierarchical Porous Carbons: Boosting the Energy Density of Supercapacitors via an Ionothermal Approach.J. Mater. Chem. A,2017, 5, 13009-13018.

[13] F. F. Yang, D. Wu, Z. Y. Luo, B. Tan,Z. L.Xie*, Hybrid Organic-Inorganic Dyeionogels: Reversibly pH-responsive Materials based Dye-ionic Liquids with Improved Structural Stability and Flexibility.Sensors and Actuators B-Chem.,2017, 249, 486-492.

[12] B.-B. Huang, L. Peng, F. F. Yang, Y. -C. Liu, andZ. -L. Xie*, Improving ORR Activity of Carbon Nanotubes by Hydrothermal Carbon Deposition Method. J. Energy. Chem.2017, 26, 712-718.

[11] Y. Wei, X. Y.Y. Zhang, Z. Y. Luo, D. Tang, C. X. Chen, T. Zhang* andZ. L. Xie*,Nitrogen-Doped Carbon Nanotube-Supported Pd Catalyst for Improved Electrocatalytic Performance toward Ethanol Electrooxidation.Nano-Micro Lett.,2017, 9: 28.

[10] B. -B. Huang, Z. -Y. Luo, J. -J. Zhang and Z. L. Xie*, 2D Quasi-ordered Nitrogen and Sulfur co-doped Carbon Materials from Ionic Liquid as Metal-free Electrocatalysts for ORR.RSC Adv.2017,7, 17941-17979.

[9] B. B. Huang and Z. L. Xie* Ionic Liquid-Nanocarbon Interface for Heterogeneous Catalysis, Wiley-VCH, Weinheim,2017,ISBN: 978-3-527-34255-6, Handbook. (Invited)

2016

[8] Z.-L. Xie, B. Frank, X. Huang, R. Schlögl, A. Trunschke*, Higher Alcohol Synthesis over Rh Catalysts: Conditioning of Rh/N-CNTs by Co and Mn Entrapped in the Support.Catal. Lett.,2016,146, 2417-2424.

[7] X. X. Lin, B. Tan, L. Peng, Z. F. Wu and Z. L. Xie*, Ionothermal Synthesis of Microporous and Mesoporous Carbon Areogels from Fructose as Electrode Materials for Supercapacitors.J. Mater. Chem. A,2016, 4, 4497-4505.

[6] A. Y. Klyushin*, R. Arrigo, Y. M. Yi, Z. L. Xie, M. Havercker, A. Knop-Gericke, R. Schlögl,Are Au Nanoparticles on Oxygen-Free Supports Catalytically Active? Top Catal.,2016, 59, 469-477.

[5] Z. F. Wu, B. Tan, Z. H. Deng, Z. L. Xie, J. J. Fu, N. N. Shen, X. Y. Huang*, Dual-Emission Luminescence of Magnesium Coordination Polymers Based on Mixed Organic Ligands. Chem-Eur J.,2016, 22, 1334-1339.

[4] Z. F. Wu, B. Tan, Z. L. Xie, J. J. Fu, X. Y. Huang*, A photochromic dual-functional Mg-CP exhibits white-emission after modification with CuI. J. Mater. Chem. C,2016, 4, 2438-2441

[3] B. Frank, Z. L. Xie, K. F. Ortega, M. Scherzer, R. Schlögl, A. Trunschke*, Modification of the carbide microstructure by N- and S-functionalization of the support in MoxC/CNT catalysts. Catal. Sci. Technol.,2016, 6, 3468-3475.

2015

[2] Z. L. Xie* and D. S. Su*, Ionic Liquid Based Approaches to Carbon Materials Synthesis.Eur. J. Inorg. Chem., 2015, 7, 1137-1147. (Invited)

[1] Z. F. Wu, B. Tan, C. F. Du, M. L. Feng, Z. L. Xie, X. Y. Huang*, An ionothermally synthesized Mg-based coordination polymer as a precursor for preparing porous carbons.CrystEngComm,2015, 17, 4288-4292.

2023年：福建省高层次B类人才

2021年：国家“万人计划”青年拔尖人才

2021年：第五届福州青年科技奖

2021年：福建省杰出青年基金

2021年：福州大学杨洪耀奖教金

2020年：福建省“雏鹰计划”青年拔尖人才

2020年：福州大学第三届“福能”奖教金

2016年：福建省境外引进C类高层次人才

2014年：福建省“闽江学者”奖励计划

2012年：德国马克斯-普朗克学会奖学金

Patents:

[1] 具有催化性能的镉金属有机框架及其制备方法和用途，专利号：ZL 201110349525.2 授权日期：2015年10月7日。

[2] 由稀土金属有机框架化合物制得的荧光探针材料及其应用，专利号：2015100998822.4 授权日期：2017年3月7日。

[3] 生物小分子直接合成杂原子掺杂石墨烯的方法，专利号：201710604048.7 实检日期：2017年10月18日。

[4] 一类用于芳香醇选择氧化反应的纳米碳负载Pd催化剂及其应用，专利号：201710519157.9 申请日期：2017年06月30日。

[5] 一种基于鸟苷水热的球与片复合纳米碳催化剂的制备方法，专利号：CN 110498403 A 授权日期：2021年6月15日。

[6] 一种锂硫电池用聚合物改性复合正极及其制备方法，专利号：CN 112599754 B 授权日期：2022年4月2日。

[7] 一种核壳结构的氮掺杂碳壳包裹碳化钼核微米球材料的制备方法，专利号：CN 202210286286.9 授权日期：2023年7月13日。