汤胜,博士、副教授、硕士生导师,武汉工程大学“人才培育发展支持计划”青年骨干人才。2006/09−2010/06,湖南师范大学,化学专业,获理学学士学位;2010/09−2015/06,中国科学院大学(中国科学院兰州化学物理研究所),分析化学专业,获理学博士学位,曾获“中国科学院朱李月华优秀博士生奖”。面向复杂样品分离分析需求,聚焦色谱分离新材料的研发与应用,致力于发展高效、高选择性的新型分离介质,构建分离分析新方法。
作为负责人主持国家自然科学基金、湖北省自然科学基金等项目,以第一/通讯作者在专业领域知名期刊发表SCI论文40余篇,近三年在中科院TOP期刊或一区期刊发表SCI论文20余篇,担任Chinese Chemical Letters、Journal of Analysis and Testing等期刊青年编委。指导和培养研究生20余名,多人获评研究生国家奖学金、优秀研究生、优秀毕业研究生、优秀硕士学位论文等。
作为骨干成员获批省级一流本科课、省级课程思政示范课程与教学团队,作为负责人获批校级一流本科课程、校级课程思政示范课程,出版高等学校“十三五规划”教材1部,获得武汉工程大学第九届教学成果奖一等奖1项。指导本科生以第一作者发表中科院二区以上论文多篇,获全国大学生生命科学竞赛一等奖等学科竞赛奖多项。曾多次获评武汉工程大学“青年岗位能手”、“优秀班主任”、“百佳导师”等荣誉称号。
招生专业及代码:化学(0703);分析化学(070302)
研究方向:色谱分析、环境分析化学
研究室:武汉工程大学流芳校区大化工楼1314实验室
联系方式:stang@wit.edu.cn;QQ:469550457
近三年发表的中科院二区以上论文:
[1] Green and mild synthesis of Ca-MOF/COF functionalized silica microspheres in an acid-base tunable deep eutectic solvent for multi-mode chromatography, Chinese Chemical Letters (2025). https://doi.org/10.1016/j.cclet.2025.111186.
[2] Metallic deep eutectic solvent derived chiral carbon dots functionalized MOF@silica composite: A new and highly efficient column packing material, Separation and Purification Technology 369 (2025) 133126.
[3] Deep eutectic solvent-based ionogel: Innovative potential as a promising chromatographic separation material, Analytica Chimica Acta 1342 (2025) 343673.
[4] A new green approach to synthesizing MIP-202@porous silica microspheres for positional isomer/enantiomer/hydrophilic separation, Chinese Chemical Letters 36 (2025) 109985.
[5] Stable ionic liquid/Zr-MOF co-modified silica microspheres: Facile construction strategy and promising chromatographic applications, Separation and Purification Technology 354 (2025) 128718.
[6] Chiral microporous organic network/covalent organic framework/silica composites: Powerful and versatile chromatographic separation materials, Separation and Purification Technology 355 (2025) 129701.
[7] Ingenious design of novel layered double hydroxide/conjugated microporous polymer modified silica gel for diversified chromatographic applications, Separation and Purification Technology 359 (2025) 130667.
[8] Deep eutectic solvent-based ionogel: Innovative potential as a promising chromatographic separation material, Analytica Chimica Acta 1342 (2025) 343673.
[9] Synergistic expression of ZIF-67 and amphiphilic polymer hydrogel in multi-mode liquid chromatographic separation, Separation and Purification Technology 349 (2024) 127827.
[10] Surface molecularly imprinted polymer/covalent organic framework/silica composite material with specific recognition ability and excellent chromatographic performance, Talanta 276 (2024) 126238.
[11] Deep eutectic supramolecular polymers based HPLC stationary phase: Green synthesis strategy and promising application prospects, Analytica Chimica Acta 1330 (2024) 343268.
[12] Innovative development of deep eutectic solvent based supramolecular hydrogel as excellent surface functional material of porous silica gel with favorable chromatographic performance, Microchemical Journal 207 (2024) 112247.
[13] Green synthesis of N‑rich carbon dot‑derived crosslinked covalent organic nanomaterial for multipurpose chromatographic applications, Microchimica Acta 191 (2024) 345.
[14] Metal/covalent organic framework@silica double-layer core-shell composite: A high-performance liquid chromatographic stationary phase, Microchemical Journal 201 (2024) 110517.
[15] Design of smart temperature-sensitive terpolymeric hydrogel for multi-applications in liquid chromatography, Journal of Chromatography A 1722 (2024) 464867.
[16] Exploring the potential applications of amphiphilic carbon dots based nanocomposite hydrogel in liquid chromatographic separations, Analytica Chimica Acta 1299 (2024) 342445.
[17] A facile creation of hydrophilic-lipophilic-balanced covalent organic frameworks with mixed-mode retention mechanisms for multiple applications in liquid chromatography, Microchemical Journal 197 (2024) 109900.
[18] Facile synthesis of a novel polymer/covalent organic framework@silica composite material in deep eutectic solvent for mixed‑mode liquid chromatographic separation, Microchimica Acta 191 (2024) 35.
[19] Ionic liquid/covalent organic framework/silica composite material: Green synthesis and chromatographic evaluation, Analytica Chimica Acta 1283 (2023) 341992.
[20] Chitosan/polyacrylic acid/octadecene double-crosslinked network hydrogel functionalized porous silica microspheres for multimode liquid chromatographic separation, Journal of Chromatography A 1709 (2023) 464390.
[21] Hydrophobic/hydrophilic separation performance evaluation of a mixed-mode ionic liquid embedded stearyl thioglycolate functionalized silica stationary phase, Journal of Chromatography A 1706 (2023) 464279.
[22] Green preparation of composite hydrogel coated hydrophobic long-chain carboxylic acid-bonded silica microspheres for mixed-mode chromatography, Microchemical Journal 193 (2023) 109104.
[23] Preparation and application of a novel imine-linked covalent organic framework@silica composite for reversed-phase and hydrophilic interaction chromatographic separations, Analytica Chimica Acta 1276 (2023) 341635.
[24] Chromatographic separation performance of silica microspheres surface-modified with triazine-containing imine-linked covalent organic frameworks, Talanta 260 (2023) 124589.
[25] Performance evaluation of 2-undecylimidazole/propyl methacrylate bifunctional silica gel for mixed-mode reversed-phase/anion-exchange chromatography, Microchemical Journal 191 (2023) 108768.
[26] Ingenious introduction of aminopropylimidazole to tune the hydrophobic selectivity of dodecyl-bonded stationary phase for environmental organic pollutants, Microchemical Journal 182 (2022) 107933.
[27] Hydrophobic and hydrophilic selectivity of a multifunctional carbonyldiimidazolium/dodecyl modified silica stationary phase, Journal of Chromatography A 1677 (2022) 463300.
[28] Innovative preparation of ureido/dodecyl dual-functionalized silica as a versatile mixed-mode stationary phase for high-resolution chromatographic separations, Journal of Chromatography A 1665 (2022) 462834.
[29] Recent advances of innovative and high-efficiency stationary phases for chromatographic separations, Trends in Analytical Chemistry 153 (2022) 116647.
