在职教师

刘山虎

实验教学中心
发布时间:2019-02-28
浏览次数:
来源: 管理员

 







   系别:化学系

   职称:教授,博士生导师

   院内行政职务:

   电话:0371-23881589

   邮箱:liushanhu@163.com

 


个人简介:

刘山虎, 1977年出生,河南省清丰县人,主要从事超浸润界面的组装及应用、电催化能源材料(产氢催化,氮还原催化)相关研究。主持完成国家自然科学基金、日本JSPS科研奖励基金、中国石油天然气集团公司委托技术项目、河南省科技攻关项目、河南省教师教育课程改革研究项目等,作为主要成员参与完成中日重大国际(地区)合作基金、日本文部省基础研究重大项目基金、信越化学工业株式会社委托基金等项目。曾获河南省科技进步奖三等奖,河南大学师德先进个人,河南大学教学优秀奖,河南大学科研优秀奖。发表论文80余篇,(ESI高被引4篇),被引5300次,H-index 43

 

研究工作经历

1996-2000  河南师范大学化学与环境科学学院本科

2004-2007  河南师范大学化学与环境科学学院硕士

2007-2010  南京大学化学化工学院博士

2010-至今  河南大学化学化工学院工作

2011-2012  日本神奈川科学技术研究院研究员

2012-2014  日本学术振兴会JSPS外国人特聘研究员

2014-2015  日本东京理科大学综合研究机构客座准教授

 

教学培养

承担本科生《分析化学》、《无机及分析化学》、《无机及分析化学实验》、《绿色化学与社会发展(通识课)》,以及研究生《专业英语》、《纳米分析化学》、《环境能源材料前沿讲座》等课程。

 

主持项目

1.            Fe3O4/金量子点双功能材料的组装与光电免疫传感,国家自然科学基金,2012.1-2014.12

2.            Organic-titania monolith for self-cleaning coating with photoinduced self-healing ability JSPS科研奖励基金,2013.1-2014.12

3.            Durable and Scalable Superhydrophobic Membranes for Efficient Oil-Water Separation  国家自然科学基金外国人青年基金(Dr. Sanjay),2020.1-2020.12

4.            基于二氧化钛纳米结构的高效室内空气净化系统,河南省科技攻关计划项目,2017.1-2018.6

5.            二氧化钛基复合材料的仿生合成及室内空气净化技术开发,科技部外专引智项目,2018.1-2021.12

6.            光催化自清洁涂层的仿生设计及光诱导自修复性能研究,河南省科技攻关计划项目,2021.1-2022.6

7.            亲油耐磨润滑材料及部件试制,中国石油天然气集团公司委托项目,2020.1-2021.3

8.            亲油疏水多孔材料关键技术转化,河南大学一流学科理工类培育项目(重大成果转化类),2020.1-2021.12

9.            疏水界面抗冰涂层研究,河南大学2019交叉学科培育计划项目,2020.1-2020.12

10.        电网及通讯设备表面抗冰涂层关键技术开发,企业委托,2022.1-2022.9

11.        青少年科普活动成效及提质增效工程,河南省科协项目,2021

12.        无机及分析化学,河南大学课程思政样板课程建设,2022

13.        小学低年级《科学》课程的教学改革与实践,河南省教师教育课程改革项目(2018-JSJYYB-006),2018.1-2018.12

14.        基于中国古代科技史料的中学化学课程思政实施路径与应用研究,河南省教师教育课程改革项目,2023.1-2023.12

 

发表论文

1.       CoS2 nanodots anchored into heteroatom-doped carbon layer via a biomimetic strategy: Boosting the oxygen evolution and supercapacitor performance, Journal of Power Sources, 2019, 436, 226862;

2.       Hierarchical ZnS@ C@ MoS2 core-shell nanostructures as efficient hydrogen evolution electrocatalyst for alkaline water electrolysis, International Journal of Hydrogen Energy, 2019, 44 (47), 25310-25318

3.       Self–cleaning superhydrophobic coatings: Potential industrial applications, Progress in Organic Coatings, 2019, 128, 52-58 (高被引)

4.       Recent advances in durability of superhydrophobic self-cleaning technology: a critical review, Progress in Organic Coatings, 2020, 138, 105381 (高被引)

5.       Recent developments in air-trapped superhydrophobic and liquid-infused slippery surfaces for anti-icing application, Progress in Organic Coatings, 2020, 137, 105373

6.       Spatial compartmentalization of cobalt phosphide in P-doped dual carbon shells for efficient alkaline overall water splitting, Inorganic Chemistry, 2020, 59 (3), 1996;

7.       Ti 3+ self-doped TiO 2− x nanowires for efficient electrocatalytic N 2 reduction to NH 3, Chemical Communications, 2020, 56 (7), 1074; (高被引)

8.       Ultrathin WS2 nanosheets vertically aligned on TiO2 nanobelts as efficient alkaline hydrogen evolution electrocatalyst, International Journal of Hydrogen Energy, 2020, 45 (3), 1697;

9.       Ultrathin VS2 nanosheets vertically aligned on NiCo2S4@ C3N4 hybrid for asymmetric supercapacitor and alkaline hydrogen evolution reaction, Applied Surface Science, 2020, 527, 146856

10.   Boosting the electrochemical performance of MoS2 nanospheres-N-doped-GQDs-rGO three-dimensional nanostructure for energy storage and conversion applications, Applied Surface Science, 2020, 504, 144441;

11.   Hydrothermally/electrochemically decorated FeSe on Ni-foam electrode: An efficient bifunctional electrocatalysts for overall water splitting in an alkaline medium, International Journal of Hydrogen Energy, 2020, 45 (51), 27182-27192

12.   Ultrathin MoS2 nanosheets in situ grown on rich defective Ni0. 96S as heterojunction bifunctional electrocatalysts for alkaline water electrolysis, International Journal of Hydrogen Energy, 2020, 45, 29929;

13.   Electrochemical nitrogen reduction: recent progress and prospects, Chemical Communications, 2021,57, 7335-7349 (高被引)

14.   Investigating the effect of Nd3+ dopant and the formation of g-C3N4/BiOI heterostructure on the microstructural, optical and photoelectrocatalytic properties of g-C3N4, Applied Surface Science, 2021, 561, 150082;

15.   Enhanced photo-electrocatalytic performance of the nano heterostructures based on Pr3+ modified g-C3N4 and BiOI, International Journal of Hydrogen Energy, 2022, 47 (77), 32903;

16.   Open and porous NiS2 nanowrinkles grown on non-stoichiometric MoOx nanorods for high-performance alkaline water electrolysis and supercapacitor, International Journal of Hydrogen Energy, 2022, 47 (32), 14404;

17.   (Fe, Ni) S2@ MoS2/NiS2 hollow heterostructure nanocubes for high-performance alkaline water electrolysis, International Journal of Hydrogen Energy, 2022, 47 (21), 11143;

18.   A Special Issue Dedicated to the 110th Anniversary of Henan University, Exploration, 2022, 2 (4), 20220101

19.   Biomaterial based fabrication of superhydrophobic textiles–A review, Materials Today Chemistry, 2022, 24, 100940

20.本草古籍中化学教学资源的开发与利用[J]. 化学教育,2022,43(19):77-82.

 

授权专利

1.  核壳结构ZnS@C@MoS2催化剂的制备方法及应用 2019.6.12ZL2019 1 0507485.6

2.  一种便携式空气净化器 2018.4.20   ZL 2018 2 0564833.4

3.  车载太阳能自驱动空气净化器 2018.4.20   ZL2018 2 0564752.4

4.  一种水质重金属去除装置  2018.9.26ZL2018 2 1569928.1

 

专著(章节)

1.       Elsevier出版社: Superhydrophobic Polymer CoatingsCHAPTER15 Superhydrophobic surfaces for oil-water separation, 2019ISBN 978-0-12-816671-0

2.       Elsevier出版社: Handbook of Greener Synthesis of Nanomaterials and Compounds, CHAPTER 25, Virus-assisted biological methods for greener synthesis of nanomaterials,, 2021,  ISBN: 978-0-12-821938-6

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