师资队伍

个人简介：

魏真真，副教授，硕士生导师。2017年3月博士毕业于东华大学纺织材料与纺织品设计专业，师从中国工程院院士俞建勇教授。2015-2016年在英国谢菲尔德大学材料科学与工程学院访学，师从Goran Ungar教授。2017年3月到苏州大学纺织与服装工程学院工作。至今，以第一或通讯作者在Energy Storage Materials, Advanced Functional Materials, Journal of Power Sources, Journal of Energy Storage, Composites Science and Technology, Composites Part B-Engineering, Chemical Engineering Journal,Langmuir, Journal of Colloid and Interface Science, ACS Applied Materials& Interfaces等学术期刊上发表SCI论文40余篇，授权发明专利8项，主持各类科研项目10项，参与编写教材4部，指导学生参与学科竞赛获奖20余项。

研究方向：

1.纤维材料在新能源领域的应用研究

重点围绕纤维基电池隔膜的结构力学强化、离子高效传输、热安全管控开展系统研究。

2.针织产品结构设计与功能开发

重点围绕针织产品的花型创新设计、功能纱线与针织结构的适配技术、织造工艺优化开展系统研究。

主讲课程：

本科生课程：针织学、产品创新设计、试验设计与优化

研究生课程：试验设计与多元分析

近五年的代表性成果：

1.荣誉及获奖

(1)江苏省科技副总

(2)中国纺织工业联合会纺织高等教育教学成果奖 特等奖

(3)江苏省高校微课教学比赛 三等奖

(4)苏州大学青年教师课堂教学竞赛 一等奖

(5)中国高校纺织品设计大赛 优秀指导教师

(6)中国化学纤维工业协会恒逸基金优秀学术论文 一等奖

2.科研项目

(1)校企合作项目，超轻薄高紧度锦纶功能面料关键技术研发

(2)江苏省产学研合作项目，无纺布基电池隔膜制备关键技术研发

(3)江苏省高等学校基础科学研究重大项目，纤维基锂电池隔膜的结构设计及其穿刺响应机制研究

(4)校企合作项目，化学纤维后处理工艺优化技术

(5)江苏省自然科学基金青年项目，共聚酯纤维复合材料中纳米颗粒的三维分布及其力学增强机理研究

3.代表性论文

[1]Wang MY; Cao H; Huang ZH; Lin ZX; Ye SY; Li Ying; Hua YZ; Wei Z*, Zhao Y*. Robust cellulose/clay composite aerogels with frame-wall like structure for superior thermal insulation and flame retardancy.Composites Part B: Engineering, 2026, 309, 113098.

[2]Hua Y, Yang S, Xing J, Li H,Wei Z*, Zhao Y*. Gradient distribution construction of ZIF particles in nanofibrous battery separator for high strength and ionic transport capacity.Journal of Energy Storage, 2025, 133: 118064.

[3]Li Y, Hua Y, Cai S, Zhou R, Wang M,Wei Z*, Zhao Y*. Separator’s contribution to the ion transport in lithium batteries.Energy Storage Materials, 2025, 82: 104636.

[4]Lin Z, Li H, Wang M, Zhou R, Li Y, Ye S,Wei Z*, Zhao Y*. Functionalized Separators for Batteries: Universality and Individuality.Advanced Functional Materials, 2025, 35: 2505100.

[5]Ren H, Wang B, Zhou R, Wu B, Yang S,Wei Z*, Zhao Y*. Fiber-Based Composite Separator with Stable Interface and High Ionic Transport Capacity for Lithium Batteries.ACS Applied Materials & Interfaces, 2025, 17(8): 12610-12620.

[6]Liang Y, Wu J, Cai S, Ren H, Wu B, Hua Y,Wei Z*, Zhao Y*. Ionic transport regulation separator co-functionalized by conductive nanoparticles and nonconductive nanorods for high performance lithium battery.Journal of Power Sources, 2025, 640: 236725.

[7]Wu B, Li Y, Liang Y, Yang S, Ren H, Lu L,Wei Z*, Zhao Y*. Attapulgite/Fe₃O₄ synergistically enable the nanofiber composite separator with high ionic transport ability for lithium batteries.Electrochimica Acta, 2025, 539: 147174.

[8]Li H, Ren H, Lin Z, Hua Y, Yuan Z,Wei Z*, Zhao Y*. Interfacial engineering of silica composited fibrous separator for high-performance lithium-ion batteries.Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2025, 726: 137956.

[9]Li J, Lu L, Liang H, Sun Y, Guo X,Wei Z*, Zhao Y*. Silkworm cocoon-inspired and robust nanofibrous composite separator with gradient structure for lithium ion batteries.Composite Structures, 2024, 339: 118161.

[10]Cai S, Ye S, Zhang M, Wang M,Wei Z*, Zhao Y*. Cocross-Linked Nanofibrous Separator with High Ion Transport Capacity for Lithium-Ion Batteries.ACS Applied Nano Materials. 2024, 7, 24148.

[11]Gu JY, Feng YT, Wei X, Zhang CC, Peng TS, Lu L,Wei Z*, Zhao Y*. Flexible fibrous separator asymmetrically coated by silica and MXene for high performance lithium batteries with enhanced safety.Journal of Power Sources, 2023. 581: 233515.

[12]Zhang K, Chen HZ, Huang HQ,Wei Z*, Zhao Y*. Water-soluble ammonium polyphosphate synchronously enables mechanically robust and flame-retardant cellulose composite separator for high safety lithium batteries.Journal of Power Sources, 2023, 558: 232627.

[13]Wei Z*, Yu LY, Lu SQ, and Zhao Y*. Reversibly thermo-responsive materials applied in lithium batteries.Energy Storage Materials, 2023. 61: 102901.

[14]Chen HZ, Wang ZC, Feng YT, Cai SY, Gao HP,Wei Z*,Zhao Y*. Cellulose-based separators for lithium batteries: Source, preparation and performance.Chemical Engineering Journal, 2023. 471: 144593.

[15]Xing J, Fan WX, Li JY, Wang ZC,Wei Z*, Zhao Y*. Orientation gradient architecture of nanofibrous separator towards mechanical enhancement and ion transport acceleration for lithium-ion batteries.Electrochimica Acta, 2023, 441: 141794.

[16]Zhou YG, Fan L, Li HQ, Cui YJ, Yu SF,Wei Z*, Zhao Y*. Fibrous separator with surface modification and micro-nano fibers lamination enabling fast ion transport for lithium-ion batteries.Chinese Journal of Polymer Science, 2023, 41(2): 222-232.

[17] Pan C, Wei X, Feng YT,Wei Z*,Zhao Y*. WO3-composited polyimide nanofibrous separator with superior mechanical properties and high capacity for lithium-ion batteries.Journal of Materials Science, 2023. 58: 10686-10698.

[18]Cai SY, Liang YX, Wu JL, Chen HZ,Wei Z*, Zhao Y*. Crosslinked PVA/citric acid nanofibrous separators with enhanced mechanical and thermal properties for lithium-ion batteries.Batteries, 2023. 9: 556.

[19]Guo T, Chi HJ,Wei Z*,Zhao Y*.Under-Oil Superhydrophilic/Superhydrophobic Janus Nanofibrous Membrane for Highly Efficient Separation of Surfactant-Stabilized Water-in-Oil Emulsions.Langmuir, 2023, 39(46): 16668-16675.

[20]Jiang S, Bi Z, Wang J, Zhao J, Fan L, Tian L, Wu Y, Yi N,Wei Z*, Gan F*. Construction of novel Cu-α-diimide interactions for enhancing thermal resistance and dimensional stability of polyimide films.Journal of Materials Research and Technology, 2023. 25: 1920-1930.

[21]Yu LY, Gu JY, Pan C, Zhang JY,Wei Z*, Zhao Y*. Recent developments of composite separators based on high-performance fibers for lithium batteries.Composites Part A-Applied Science and Manufacturing, 2022, 162: 107132.

[22]Cheng C,Wei Z*, Gu J, Wu Z, Zhao Y*. Rational design of Janus nanofibrous membranes with novel under-oil superhydrophilic/superhydrophobic asymmetric wettability for water-in-diesel emulsion separation.Journal of Colloid and Interface Science, 2022, 606: 1563-1571.

[23]Guo XS, Li JY, Xing JX, Zhang K, Zhou YG, Pan C,Wei Z*, Zhao Y*. Silkworm cocoon layer with gradient structure as separator for lithium-ion battery.Energy Technology, 2022, 10(4): 2100996.

[24]Xing JX, Li JY, Fan WX, Zhao TQ, Chen XY, Li HQ, Cui YJ, Wei Z*, Zhao Y*. A review on nanofibrous separators towards enhanced mechanical properties for lithium-ion batteries.Composites Part B-Engineering, 2022, 243: 110105.

[25]Wang YB, Zhang J*, Li W, Xie XL, Yu WW, Xie L,Wei Z*, Guo RJ, Yan H, Zheng Q. Antibacterial poly(butylene succinate-co-terephthalate)/titanium dioxide/copper oxide nanocomposites films for food packaging applications.Food Packaging and Shelf Life, 2022, 34: 101004.

[26]Yang SG,Wei ZZ, Cseh L, Kazemi P, Zeng XB, Xie HJ, Saba H, Ungar G*. Bowls, vases and goblets-the microcrockery of polymer and nanocomposite morphology revealed by two-photon optical tomography.Nature Communications, 2021, 12(1): 5054.

[27]Li JY, Zhang YZ, Shang R, Cheng C, Cheng Y, Xing JX,Wei Z*, Zhao Y*. Recent advances in lithium-ion battery separators with reversible/irreversible thermal shutdown capability.Energy Storage Materials, 2021, 43: 143-157.

[28]Wei Z*, Gu JY, Zhang FR, Pan ZJ, Zhao Y*. Core-shell structured nanofibers for lithium ion battery separator with wide shutdown temperature window and stable electrochemical performance. ACS Applied Polymer Materials, 2020, 2(5): 1989-1996.

4.授权专利

[1]一种锂电池用纤维隔膜及其制备方法:ZL202310042607.5.

[2]一种高强阻燃纤维素膜的制备方法:ZL202211056346.4

[3]高抗拉强度和高离子电导率的电纺锂电池隔膜及其制法:ZL202111504452.X.

[4]一种锂电池用纤维素隔膜的制备方法:ZL202211046856.3.

[5]一种锂电池隔膜用生物质纤维复合膜及其制备方法:ZL202010417300.5.

[6]一种耐穿刺纤维复合膜及其制备方法:ZL202010417382.3.

[7]一种锂离子电池隔膜及其制备方法:ZL201910767161.6.

[8]一种超亲水聚酯纳米纤维膜及其制备方法:ZL201710958227.0

联系方式：zzwei@suda.edu.cn

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