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肖蓓蓓 副教授 能源与动力学院 个人邮箱： 524395268@qq.com 办公地点： 教四101 通讯地址： 江苏镇江梦溪路2号 邮政编码： 212003 传真： 您是第8340 位访问者 个人简介 个人基本信息肖蓓蓓，女，1987年生，工学博士/副教授/轮机工程学硕，现任江苏科技大学能源与动力学院新能源系系主任。研究兴趣主要侧重于燃料电池催化剂的设计与优化以及新能源化学储能过程转变。总发表论文100余篇，总引用次数2400余次，H因子27，第一/通讯作者（含共一/共通）论文34篇，ESI全球1%高引用论文7篇，封面论文2篇，热点论文3篇。已毕业五届研究生；在读研究生6名。科研与学术工作经历2015/3 – 2017/9，江苏科技大学，能源与动力学院，讲师2017/9 – 至今，江苏科技大学，能源与动力学院，副教授2020/3 – 至今，江苏科技大学，能源与动力学院，新能源系系主任2022/5 – 2023/5，Centre national de la recherché scientifique (CNRS)，Adsorption in the Department of Porous and Hybrid materials within the Institute Charles Gerhardt Montpellier，导师：Guillaume Maurin科研项目[1]2016-2018 主族元素掺杂Pt基材料催化氧气还原反应的第一原理研究国家自然科学青年基金 主持[2]2015-2018 Pt系氧气还原反应催化剂的优化设计江苏科技大学基金 主持[3]2020-2022 国家留学基金委项目国家公派高级研究学者、访问学者、博士后项目 主持[4]2020-2021 新型固N2电解阴极的设计与机理研究 江苏省研究生科研与实践创新计划项目(杨磊) 指导教师[5]2020-2022 高性能燃料电池催化剂层的设计与优化 招商局海工科研创新基金项目 主持[6]2023-2024 五配位CoN4增强氧还原催化性能的第一性原理研究 江苏省研究生科研与实践创新计划项目(张泽) 指导教师代表性论文[1]Xiao, B. B.; Zhu, Y. F.; Lang, X. Y.; Wen, Z.; Jiang, Q., Al13@Pt42 Core-Shell Cluster for Oxygen Reduction Reaction, Sci. Rep. 4, 5205,2014.[2]Xiao, B. B.; Lang, X. Y.; Jiang, Q., Pt Monatomic Wire Supported on Graphene Nanoribbon for Oxygen Reduction Reaction, RSC Adv. 4, 28400, 2014.[3]Lang X. Y.+; Han, G. F.+; Xiao, B. B.+; Gu, L.; Wen, Z.; Zhu, Y. F.; Zhao, M.; Li, J. C. Jiang, Q.,Mesostructured Intermetallic Compounds of Platinum and Non-transition Metals for Enhanced Electrocatalysis of Oxygen Reduction Reaction., Adv. Funct. Mater. 25, 230, 2015.(co-first authors) [4]Xiao, B. B.; Zhang, P.; Han, L. P.; Wen. Z., Functional MoS2 by the Co/Ni doping as the catalyst for oxygen reduction reaction., Appl. Surf. Sci. 354, 221, 2015. [5]Xiao, B. B.; Jiang, X. B.; Jiang, Q., Density Functional Theory Study of Oxygen Reduction Reaction on Pt/Pd3Al(111) Alloy Electrocatalyst., Phys. Chem. Chem. Phys.18, 14234, 2016[6] Xiao, B. B.; Jiang, X. B.; Yang, X. L.; Jiang, Q.; Zheng, F. The segregation resistance of the sandwich Pt2ML/Os/Pd3Al catalyst for oxygen reduction reaction: A Density Functional Theory Study. Phys. Chem. Chem. Phys.18, 30174, 2016 [7] Xiao, B. B.; Liu, H. Y.; Jiang, X. B.; Yu, Z. D.; Jiang, Q.A BifunctionalTwo Dimensional TM3(HHTP)2 monolayer and its variations for Oxygen Electrode Reactions.RSC Adv. 7, 54332, 2017.[8]Xiao, B. B.; Zhu, H.; Liu, H. Y.; Jiang, X. B.; Jiang, Q. The Activity Improvement of the TM3(hexaiminotriphenylene)2 Monolayer for Oxygen Reduction Electrocatalysis: A Density Functional Theory Study.Front. Chem. 6, 351, 2018. [9]Zhu, H.; Liu, H. Y.; Yang, L.; Xiao, B. B.* How to boost the activity of the monolayer Pt supported on TiC catalyts for oxygen reduction reaction: A Density Functional Theory Study. Mater.12, 1560, 2019[10] Han, Gao-Feng…; Xiao, Bei-Bei*; Kim, Seok-Jin; Li, Feng; Ahmad, Ishfaq; Jeon, In-Yup; Baek, Jong-Beom*, Tuning edge-oxygenated groups on graphitic carbon materials against corrosion. Nano Energy 66, 104112, 2019 (co-corresponding authors) [11] Xiao, B. B.; Liu, H. Y.; Yang, L.; Song, E. H.; Jiang, X. B.; Jiang, Q. Design effective graphene with TM/O moiety for the oxygen electrode reaction. ACS Appl. Energy Mater. 3, 260, 2020[12] Xiao, B. B.; Yang, L.; Yu, L. B.; Song, E. H.; Jiang, Q. The VN3 embedded graphane with improved selectivity for nitrogen fixation. Appl. Surf. Sci. 513, 145855, 2020.[13] Yang, L.; Chen, F. X.; Song, E. H.; Yuan, Z. F.; Xiao, B. B.* Feasibility of N2 reduction on the V anchored 1T-MoS2 monolayer: a density functional theory study. ChemPhysChem 21, 1235-1242, 2020. (Front Cover: 21, 1215-1215, 2020; Cover Feature: 21, 1217-1217, 2020)[14] Wenwu Zhong,* Wenguang Tu*, Zongpeng Wang, Zhiping Lin, Aijiao Xu, Xiufang Ye, Dongchu Chen, Beibei Xiao*, Ultralow-temperature assisted synthesis of single platinum atoms anchored on carbon nanotubes for efficiently electrocatalytic acidic hydrogen evolution. J. Energ. Chem. 51, 280-284, 2020.  high-cited, hot paper[15] Zongpeng Wang†, Beibei Xiao†, Zhiping Lin, Shijie Shen, Aijiao Xu, Yuchao Chen, Wenwu Zhong*, In-situ surface decoration of RuO2 nanoparticles by laser ablation for improved oxygen evolution reaction activity in both acid and alkali solutions. J. Energ. Chem. 54, 510-518, 2020. (co-first authors) high-cited[16] Shuang Wanga, †, Beibei Xiaob, †, Shijie Shena,*, Kai Songa, Zhiping Lina, Zongpeng Wanga, Yuchao Chena, Wenwu Zhonga,*, Cobalt doping of FePS3 promotes intrinsic active sites for efficient hydrogen evolution reaction. Nanoscale 12, 14459-14464, 2020. (co-first authors)[17] L. Yang, L. B. Yu, S. S. Liu, E. H. Song, Y. D. Song, Xiao, B. B*. The FeN3 Doped Fluorographene for N2 Fixation: A Density Functional Theory Study. ChemistrySelect. 2020.[18] Xiao, B. B.; Yang, L.; Liu, H. Y.; Jiang, X. B.; Kochetov, V.; Song, E. H.; Jiang, Q. Designing Fluorographene with FeN4 and CoN4 Moieties for Oxygen Electrode Reaction: A Density Functional Theory Study. Appl. Surf. Sci. 2021, 537, 147846.[19]Wenwu Zhong†, Beibei Xiao†, Zhiping Lin, Zongpeng Wang, Liangai Huang, Shijie Shen, Qinghua Zhang and Lin Gu, RhSe2: a superior 3D electrocatalyst with multiple active facets for hydrogen evolution reaction in both acid and alkaline solutions. Adv. Mater. 2021, 2007894.(co-first authors) high-cited, hot paper[20] Zhiping Lin†, BeiBei Xiao†, Zongpeng Wang, Shijie Shen, Liangai Huang, Jitang Zhang, Fanqi Meng, Qinghua Zhang, Lin Gu, and Wenwu Zhong, anar-coordination PdSe2 nanosheets as highly active electrocatalyst for hydrogen evolution reaction. Adv. Funct. Mater.2021, 2102321(co-first authors) high-cited[21] L. Yang, F. X. Chen, M. Wu, E. H. Song, B. B. Xiao*, Q. Jiang*, N2 fixation via Mo decroated zigzag of graphene nanoribbon. Appl. Surf. Sci.2021, 568, 150867.[22] Zongpeng Wang1,+, Beibei Xiao2,+, Zhiping Lin1, Yaping Xu1, Yan Lin1, Fanqi Meng3, Qinghua Zhang3, Lin Gu3, Baizeng Fang4, Shaojun Guo5 and Wenwu Zhong1,*, PtSe2/Pt heterointerface with reduced coordinate for boosted hydrogen evolution reaction. Angew. Chem. Int. Ed., 2021,60, 23388 (co-first authors) high-cited[23] Liu, S. S.; Huang, Q. Y.; Wang, L. L.; Song, E. H.; Xiao, B. B*. Boosting Hydrogen Evolution Activity of Transition Meta-Nitrogen embedded Graphene through Introducing Secondary Transition Metal. Surf. Inter., 2022, 29, 101714[24] L. B. Yu, Q. Y. Huang, J. Wu, E. H. Song, B. B. Xiao*, Spatial-five coordination promotes the high efficiency of CoN4 moiety in graphene-based bilayer for oxygen reduction electrocatalysis: A density functional theory study, Chinese Journal of Chemical Engineering, 2022[25] B. B. Xiao*; Q. Y. Huang.; J. Wu.; E. H. Song; Q. Jiang*, Tetragonal Transition Metal Selenide for Hydrogen Evolution. Appl. Surf. Sci. 2022, 591, 153249[26] Wu Jing, Yu Libing, Liu Shuaishuai, Huang Qiuyan, Jiang Shanshan, Anton Matveev, Wang, Lianli, Song Erhong*, Xiao Beibei*, The NiN4/Cr embedded graphene for electrochemical nitrogen fixation, J. Inorg. Mater., 2022, 37, 1141.[27] Zhiping Lin, BeiBei Xiao, Min Huang, Linghui Yan, Zongpeng Wang, Yucong Huang, Shijie Shen, Qinghua Zhang, Lin Gu, Wenwu Zhong*, Realizing negatively charged metal atoms through controllable d-electron transfer in ternary Ir1-xRhxSb intermetallic alloy for hydrogen evolution reaction. Adv. Energy Mater. 2022, 2200855 (co-first authors) (Back Cover: 12, 25, 2270108) high-cited[28] Wu, J.; Yang, L; Liu, X.; Xiao, B. B.*; Ao, Z. M.*, Transition metal heteroatom decorated bismuthene catalyst for ammonia synthesis: A density functional theory study. Chin. Chem. Lett. 2022.[29] B. B. Xiao*, Z. Zhang, L. B. Yu, S. S. Liu, J. Wu, Q. Y. Huang, E. H. Song, L. L. Wang, Boosting Oxygen Reduction Electrocatalysis of Graphene-Based Bilayer Heterojunction, Surf. Inter., 2022, 33, 102232[30] Q. Y. Huang.; X. Liu, J. Wu.; B. B. Xiao*; Z. M. Ao*, Dopant-Vacancy Activiated Tetragonal Transition Metal Selenide for Improved Hydrogen Evolution. Chin. Chem. Lett. 2022[31] J. Wu; L. Yang; X. Liu; Z. Zhang; S. P. Liu; B. B. Xiao*, ZrN6-doped graphene for ammonia synthesis: A density functional theory study.ChemPhysChem 2023, 24, e202200864[32] Lei, Yang; Jiake Fan; Bei-Bei Xiao*; Weihua Zhu*, Unveiling “Sabatier principle” for electrocatalytic nitric oxide reduction on singlecluster catalysts: A DFT and machine learning guideline, Chem. Eng. J., 2023, 468, 143823 研究方向 1.燃料电池2.电化学反应3.表界面催化4.量化计算 教育经历 2009/9 - 2014/12，吉林大学，材料学，博士（硕博连读），导师：蒋青2005/9 - 2009/7，吉林大学，高分子材料科学与工程，学士 课程教学 主讲课程1.能源工程导论（校公选课）2.工程热力学3.能源化学（研究生）课程建设[1]肖蓓蓓，万超，杨宗明，孔为，卞婷，王秀珍，基于混合式教学的考核方式与评价机制研究----以新能源科学与工程专业为例，江苏省高等教育学会十四五高等教育科学研究规划课题，2022[2]肖蓓蓓，姜姗姗，卞婷，张刘挺，魏涛，教改示范课程-机械制造与材料基础，校级教改，2020[3]夏兆旺，肖蓓蓓，基于船舶类创新型工程科技人才培养的研究生导师团队建设研究，校级教改，2017[4]陈代芬，肖建昆，孔为，肖蓓蓓，于子冬，我校能源与动力工程专业大学生研究计划实施方案研究，校级教改，2016教改论文[1]肖蓓蓓，姜小宝，Materials Studio在材料学科教学中的应用初探，吉林教育，2016.[2]肖蓓蓓，杨兴林，浅谈专业英语的学习，时代教育，2017[3]肖蓓蓓，夏兆旺，浅谈机械制造与材料基础的学习，教育教学论坛，2017[4]肖蓓蓓，夏兆旺，探索卓越工程师培养前提下机械制造与材料基础的教学模式，教育教学论坛，2017[5]肖蓓蓓，姜小宝，基于项目教学法的《机械制造与材料基础》教学模式，当代教育实践与教学研究，2019[6]肖蓓蓓，姜小宝，线上线下混合式教学的一点思考――新能源科学与工程专业基础课《工程热力学》为例，产业与科技论坛，2023教学获奖[1]2016年能源与动力工程教学优[2]2016-2017年苏理工本部来港教学质量奖[3]2019-2020年江苏科技大学优秀教师[4]2020-2021年江苏科技大学新能源教工党支部优秀党员[5]2020-2021年江苏科技大学教学A[6]2021年江苏科技大学师德优秀[7]2021-2022年江苏科技大学教学A学生培养[1]2016届毕业设计（论文）团队优秀，黄烨[2]2018年校级本科生创新计划，李锦峰[3]2018届毕业设计优秀论文(校级)，蔡蕾琼[4]2020年毕业设计优秀论文(校级)，王倩[5]2020届毕业设计优秀论文(院级)，黄鑫，校级优秀毕业生[6]2020年研究生国家奖学金，杨磊[7] 2021年毕业设计优秀论文(校级)，杨磊，校级优秀硕士毕业生，校级优秀考博生[8] 2022年“车谷杯”第九届中国研究生能源装备创新设计大赛，黄秋艳，刘昕，三等奖[9] 2022年江苏省优秀学术学位硕士学位论文，杨磊，江苏省教育厅 科研项目 专利成果 科研团队 获奖动态 教学随笔 论文著作