李英儒
发布时间:2022-03-04 点击量:3852 来源: 作者:
李英儒(1989.01 - ),河北秦皇岛人,副教授,理学博士,硕士生导师。现任智能科学与工程学院智能工程系教师。
研究方向:新材料的制备、性能与应用,高分子材料成型加工技术。
联系方式:liyingru@outlook.com
教育经历
2011-08 至 2016-07, 清华大学, 化学, 博士,导师:石高全
2007-08 至 2011-07, 清华大学, 高分子材料与工程, 学士
工作经历
2022-02 至 今, 湖北民族大学, 智能科学与工程学研, 讲师
2020-07 至 2022-02, 湖北民族大学, 新材料与机电工程学院, 讲师
2016-07 至 2020-06, 中国工程物理研究院, 材料研究所, 助理研究员
授课经历
主要讲授《工程材料及热处理》《工程伦理》《高分子化学与物理基础》等课程。
主要科研项目
[1] 国家自然科学基金委员会, 青年科学基金项目, 21805251, 石墨烯/二氧化铀复合纳米陶瓷的制备与性能, 2019-01-01 至 2021-12-31, 23.3万元, 在研, 主持
[2] 国家自然科学基金委员会, 面上项目, 51673108, 柔性石墨烯电极材料的制备及其性能研究, 2017-01-01 至 2020-12-31, 62万元, 结题, 参与
[3] 超轻弹性体绿色制造国家民委重点实验室(湖北民族大学), 校级项目, PT092002, 基于石墨烯 Pickering 乳液的弹性体多孔复合材料的制备技术, 2020-07 至今, 4万元, 在研, 主持
[4] 湖北民族大学, 校级项目, PY21021, 三明治型石墨烯复合物的制备与其润滑应用, 2021-01 至今, 4万元, 在研, 主持
[5] 湖北省教育厅, 厅局级纵向自科项目, Q20211905, 三明治型石墨烯/纳米颗粒复合材料设计及电磁屏蔽性能研究, 2021-01 至今, 2万元, 在研, 主持
[6] 北京海纳天工科技有限公司,氧化石墨烯试制合同,2万元,在研
发明专利
[1] 李英儒; 杨善丽; 邵浪; 王少飞; 邓辉; 王铭 ; 一种基于强碱切割氧化石墨制备碳量子点的方法、其产品及应用, 2018-4-3, 中国, CN201810286120.0
[2] 李英儒; 任一鸣; 邵浪; 唐浩; 蔡定洲 ; 一种原位合成四氧化三锰/石墨烯复合吸附剂的方法、其产品及应用, 2018-4-3, 中国, ZL201810286119.8
[3] 何永勇; 赵军; 李英儒; 毛俊元; 雒建斌 ; 石墨烯/四氧化三锰复合纳米润滑添加剂及其合成方法, 2017-10-16, 中国, CN201710958604.0
[4] 何永勇; 赵军; 李英儒; 毛俊元; 雒建斌 ; 制备膨化石墨烯润滑剂添加剂的方法、膨化石墨烯剂滑油添加剂和润滑剂, 2016-11-1, 中国, ZL201610942793.8
[5] 赵军; 黄轶遥; 李英儒; 刘益江; 高彤; 李庆展; 李双喜 ; 一种石墨烯/金属氧化物纳米复合润滑材料制备方法, 2019-11-2, 中国, CN201911062282.7
主要论文
参与发表论文近60篇,H-index 23,总被引超2000次。代表性论文如下:
[1] Macroporous Graphene Monoliths via an Improved Hydrothermal Process. Advanced Materials, 2014, 26(28), 4789-4793.
[2] "Pottery" of Porous Graphene Materials[J]. Advanced Electronic Materials, 2015, 1(5), 1500004.
[3] Highly Exfoliated Reduced Graphite Oxide Powders as Efficient Lubricant Oil Additives, Advanced Materials Interfaces, 2016, 3(22), 1600700
[4] Synthesis of thermally reduced graphite oxide in sulfuric acid and its application as an efficient lubrication additive, Tribology International, 2017, 116, 303-309
[5] Influence of macroscopic defects on the corrosion behavior of U-0.79 wt%Ti alloy in sodium chloride solution, Physical Chemistry Chemical Physics, 2018, 20(2), 765-774
[6] Exploring Uranyl/Salicylate/Hematite Binary and Ternary Complexes by Attenuated-Total-Reflection Infrared Spectroscopy, Chemistryselect, 2018, 3(17), 4570-4575
[7] In Situ Green Synthesis of the New Sandwichlike Nanostructure of Mn3O4/Graphene as Lubricant Additives, ACS Applied Materials & Interfaces, 2019, 11(40), 36931-36938
[8] Influences of pH Values' Changes on the Oxide Film of U-0.79 wt.% Ti Alloy in Aqueous SolutionA Combined Study of Traditional Electrochemical Tests and Scanning Reference Electrode Technique, Coatings, 2019, 9(4), 224
[9] Synthesis of sandwich-like Mn3O4@reduced graphene oxide nano-composites via modified Hummers' method and its application as uranyl adsorbents, Heliyon, 2019, 5(6), e01972
[10] The physical chemistry of uranium (VI) immobilization on manganese oxides, Journal of Hazardous Materials, 2020, 391, 122207
[11] A novel synthesis of graphene quantum dots via thermal treatment of crude graphite oxide in a dry and alkaline condition, and their application in uranyl detection, Heliyon, 2020, 6(9), e04533
[12] Inhibitive Effect of NO3- on the Corrosion Behavior of U-0.79wt%Ti Alloy in NaCl Solution, Rare Metal Materials and Engineering, 2020, 49(1), 101-108
[13] Hydrothermal synthesis of uranium dioxide and graphene composite and its application as an additive for uranium-dioxide-based accident tolerant fuel, Ceramic International, 2021, 47, 11249-11256
[14] Synthesis of graphene gel loading TBP via a one-step method, and its application for uranyl extraction, Separation and Purification Technology, 2021, 260, 118224
[15] Synthesis of composite of graphene and UO3 composite via one-step solution chemical reaction and its application to UO2-based accident tolerant fuel, Ceramics International, 2021, 47(23): 33047-33056.
[16] Synthesis of novel CuO@Graphene nanocomposites for lubrication application via a convenient and economical method, Wear, 2022, 498-499, 204323