【王景涛】郑州大学化工与能源学院研究生导师介绍

信息发布

　　王景涛 男 出生年月 1984年11月

　　学历/学位 博士 学科专业 化学工艺

　　毕业院校天津大学

　　职称/职务 教授/化学工程与工艺系主任

　　导师类别 博士生导师、硕士生导师

　　所属一级学科化学工程与技术

　　学科方向 膜与膜过程、新能源技术

　　科研团队先进分离技术及相关材料

　　社会兼职 JACS, Journal Materials Chemistry A, Journal of power sources, Journal of Membrane Science和ACS Applied Materials & Interfaces等12个期刊审稿人

　　电话或手机 0371-63887135个人网页/微薄

　　电子信箱 jingtaowang@zzu.edu.cn QQ号码

　　通讯地址 郑州市科学大道100号 邮编 450001

　　招生一级学科化学工程与技术

　　招生二级学科/专业注册（主招）专业 化学工艺

　　兼招专业：化学工程应用化学

　　对考生要求

　　学风端正、踏实肯干、诚实守信、胆大心细；具有较强的创新意识、较高的数学与英语水平；有出国读博或博士后意向者。

　　1. 学习经历

　　2003.09-2007.06天津大学 本科分子科学与工程专业(其中2003.09-2005.06 在南开大学化学学院学习)

　　2007.09-2009.01天津大学 硕士化学工艺专业

　　2009.03-2012.01天津大学 博士化学工艺专业

　　2. 工作经历

　　2012-2014 郑州大学化工与能源学院讲师（教学秘书）

　　2015-2016 郑州大学化工与能源学院副教授（系主任）

　　2016-至今 郑州大学化工与能源学院教授（校直聘，系主任）

　　开设课程：

　　1. 本科生专业基础课程：“化工原理（大三）”

　　2. 本科生专业课程：“新型分离技术（大四）”

　　3. 本科生专业实践课程：“认识实习（大三）”

　　4. 本科生专业实践课程：“课程设计（大四）”

　　研究领域或方向

　　研究领域：“膜分离技术及其相关应用”，侧重于氢燃料电池、超级电容器、有机溶剂纳滤关键膜材料的研制及相关基础理论研究。

　　基于能源和环境问题，以膜材料设计与调控为中心，以物质传递/传导为切入点，聚焦现代化工新工艺开发与过程强化。在能源方面，开发高性能传导膜与电极材料并研究其构效关系，提高氢燃料电池及超级电容器效率和寿命，促进绿色、高效新能源技术发展；在环境方面，基于制备方法及材料创新开发高性能有机剂纳滤膜，并系统研究其有机溶剂处理回用性能。

　　代表性科研项目（主持）

　　[1] 国家自然科学基金 面上项目：“多级孔结构纤维复合膜微结构调控与质子传递过程强化”，2016.01-2019.12。

　　[2] 国家自然科学基金 青年基金：“无水质子传递通道的仿生构建与离子液体质子传递机理研究”，2013.01-2015.12。

　　[3] 中国博士后科学基金 批特别资助：“纤维复合膜质子传导特性及其强化机制研究”，2014.07-2016.06。

　　[4] 中国博士后科学基金 面上项目：“基于酸碱对构建质子传递通道及其微环境优化”，2012.07-2014.06。

　　[5] 河南省教育厅：“高传导质子交换膜的制备及其燃料电池性能研究”，2015.01-2016.12。

　　[6] 河南省人力资源和社会保障厅：“新型质子交换膜开发及氢燃料电池性能研究”，2012.07-2015.12。

　　[7] 郑州大学：“杂化法制备高传导质子交换膜及传递通道构建”，2012.03-2017.02。

　　代表性科技奖励

　　[1] 郑州大学“三育人”先进个人。

　　[2] 郑州大学优秀班主任。

　　[3] 指导研究生获研究生国家奖学金（6人）、国家级大学生创新性实验计划项目（4项）、郑州大学校级百优研究生（8人）。

　　主要成果、获奖情况、荣誉称号

　　主要代表性论文（第一作者和通讯作者）

　　2016年：

　　[36] Ti3C2Tx filler effect on the proton conduction property of polymer electrolyte membrane. ACS Applied Materials & Interfaces, 2016, 8, 20352-20363. (1区, IF=7.145)

　　[35] Constructing ionic liquid-filled proton transfer channels within nanocomposite membrane by using functionalized graphene oxide. ACS Applied Materials & Interfaces, 2016, 8, 588-599. (1区, IF=7.145)

　　[34] Polymer-Ti3C2Tx composite membranes to overcome the trade-off in solvent resistant nanofiltration for alcohol-based system. Journal of Membrane Science, 2016, 515, 175-188. (1区, IF=5.557)

　　[33] Constructing dual-interfacial proton-conducting pathways in nanofibrous composite membrane for efficient proton transfer. Journal of Membrane Science, 2016, 505, 108-118. (1区, IF=5.557)

　　[32] Embedding sulfonated lithium ion-sieves into polyelectrolyte membrane to construct efficient proton conduction pathways. Journal of Membrane Science, 2016, 501, 109-122. (1区, IF=5.557)

　　[31] Tuning the performance of anion exchange membranes by embedding multifunctional nanotubes into a polymer matrix. Journal of Membrane Science, 2016, 498, 242-253. (1区, IF=5.557)

　　[30] Polymer-inorganic hybrid proton conductive membranes: effect of the interfacial transfer pathways. Electrochimica Acta, 2016, 212, 426-439. (1区, IF=4.803)

　　[29] Tuning the microstructure and permeation property of thin film nanocomposite membrane by functionalized inorganic nanospheres for solvent resistant nanofiltration. Separation and Purification Technology, 2016, 165, 60–70. (2区, IF=3.299)

　　[28] Composite anion exchange membrane from quaternized polymer spheres with tunable and enhanced hydroxide conduction property. Industrial & Engineering Chemistry Research, 2016, 55, 9064–9076. (2区, IF=2.567)

　　2015年：

　　[27] Synergistic proton transfer through nanofibrous composite membranes by suitably combining proton carriers from the nanofiber mat and pore-filling matrix. Journal of Materials Chemistry A, 2015, 3, 21832–21841. (1区, IF=8.262)

　　[26] Constructing proton-conductive highways within an ionomer membrane by embedding sulfonated polymer brush modified graphene oxide. Journal of Power Sources, 2015, 286, 445–457. (1区, IF=6.333)

　　[25] Polyelectrolyte microcapsules as ionic liquid reservoirs within ionomer membrane to confer high anhydrous proton conductivity. Journal of Power Sources, 2015, 279, 667–677. (1区, IF=6.333)

　　[24] Anhydrous proton exchange membranes comprising of chitosan and phosphorylated graphene oxide for elevated temperature fuel cells. Journal of Membrane Science, 2015, 495, 48–60. (1区, IF=5.557)

　　[23] Enhanced proton conductivities of nanofibrous composite membranes enabled by acid-base pairs under hydrated and anhydrous conditions. Journal of Membrane Science, 2015, 482, 1–12. (1区, IF=5.557)

　　[22] Enhanced anhydrous proton conductivity of polymer electrolyte membrane enabled by facile ionic liquid-based hoping pathways. Journal of Membrane Science, 2015, 476, 136–147. (1区, IF=5.557)

　　[21] Anhydrous proton exchange membrane of sulfonated poly(ether ether ketone) enabled by polydopamine-modified silica nanoparticles. Electrochimica Acta, 2015, 152, 443–455. (1区, IF=4.803)

　　[20] Tunable solvent permeation properties of thin film nanocomposite membrane by constructing dual-pathways using cyclodextrins for organic solvent nanofiltration. ACS Sustainable Chemistry & Engineering, 2015, 3, 1925–1933. (2区, IF=5.267)

　　[19] Graphene oxide-embedded nanocomposite membrane for solvent resistant nanofiltration with enhanced rejection ability. Chemical Engineering Science, 2015, 138, 227–238. (2区, IF=2.750)

　　[18] Tuning the performance of composite membranes by optimizing PDMS content and cross-linking time for solvent resistant nanofiltration. Industrial & Engineering Chemistry Research, 2015, 54, 6175–6186. (2区, IF=2.567)

　　[17] Nanohybrid membranes with hydroxide ion transport highways constructed from imidazolium-functionalized graphene oxide. RSC Advances, 2015, 5, 88736–88747. (3区, IF=3.289)

　　2014年：

　　[16] Polydopamine-modified graphene oxide nanocomposite membrane for proton exchange membrane fuel cell under anhydrous conditions. Journal of Materials Chemistry A, 2014, 2, 9548–9558. (1区, IF=8.262)

　　[15] Enhancement of proton conductivity of chitosan membrane enabled by sulfonated graphene oxide under both hydrated and anhydrous conditions. Journal of Power Sources, 2014, 269, 898–911. (1区, IF=6.333)

　　[14] Mineralization-inspired preparation of composite membranes with polyethyleneimine–nanoparticle hybrid active layer for solvent resistant nanofiltration. Journal of Membrane Science, 2014, 470, 70–79. (1区，IF=5.557)

　　[13] Enhanced proton conduction of chitosan membrane enabled by halloysite nanotubes bearing sulfonate polyelectrolyte brushes. Journal of Membrane Science, 2014, 454, 220–232. (1区, IF=5.557)

　　[12] Enhancement of proton conductivity of polymer electrolyte membrane enabled by sulfonated nanotubes. International Journal of Hydrogen Energy, 2014, 39, 974 –986. (2区, IF=3.205)

　　[11] Cross-linked polyacrylonitrile/polyethyleneimine–polydimethylsiloxane composite membrane for solvent resistant nanofiltration. Chemical Engineering Science, 2014, 106, 157–166. (2区, IF=2.750)

　　2013年：

　　[10] Independent control of water retention and acid–base pairing through double-shelled microcapsules to confer membranes with enhanced proton conduction under low humidity. Journal of Materials Chemistry A, 2013, 1, 2267–2277. (1区, IF=8.262)

　　[9] Enhanced proton conductivity of sulfonated poly(ether ether ketone) membrane embedded by dopamine modified nanotubes for proton exchange membrane fuel cell. Fuel cells, 2013, 13, 1155–1165. (3区, IF=2.080)

　　2012年：

　　[8] Enhancement of proton conduction at low humidity by incorporating imidazole microcapsules into polymer electrolyte membranes. Advanced Functional Materials, 2012, 22, 4539–4546. (1区, IF=11.382)

　　2011年：

　　[7] Enhanced water retention by using polymeric microcapsules to confer high proton conductivity on membranes at low humidity. Advanced Functional Materials, 2011, 21, 971–978. (1区, IF=11.382)

　　2010年：

　　[6] Fabrication and performances of solid superacid embedded chitosan hybrid membranes for direct methanol fuel cell. Journal of Power Sources, 2010, 195, 2526–2533. (1区, IF=6.333)

　　[5] Simultaneously enhanced methanol barrier and proton conductive properties of phosphorylated titanate nanotubes embedded nanocomposite membranes. Journal of Power Sources, 2010, 195, 1015–1023. (1区, IF=6.333)

　　[4] Enhancing proton conduction and methanol barrier performance of sulfonated poly(ether ether ketone) membrane by incorporated polymer carboxylic acid spheres. Journal of Membrane Science, 2010, 364, 253–262. (1区, IF=5.557)

　　2009年：

　　[3] A facile surface modification of Nafion membrane by the formation of self-polymerized dopamine nano-layer to enhance the methanol barrier property. Journal of Power Sources, 2009, 192, 336–343. (1区, IF=6.333)

　　[2] Tuning the performance of direct methanol fuel cell membranes by embedding multifunctional inorganic submicrospheres into polymer matrix. Journal of Power Sources, 2009, 188, 64–74. (1区, IF=6.333)

　　2008年：

　　[1] Effect of zeolites on chitosan/zeolite hybrid membranes for direct methanol fuel cell. Journal of Power Sources, 2008, 178, 9–19. (1区, IF=6.333)