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王昕璐 副教授

于2020-04-30录入

姓名:王昕璐



职称:副教授 硕士生导师 化学博士

办公室/实验室地点:长春理工大学南区实训楼936

电话:QQ 924889135

电子信箱:xinluwang@163.com, wangxinlu@cust.edu.cn

一、主要学习工作经历

() 教育背景

2007-092012-07,中国科学院长春应用化学研究所,稀土资源利用国家重点实验室,无机化学硕博连读,博士

() 工作经历

12018-01至现在,长春理工大学,化学与环境工程学院,副教授

22018-102019-10,美国伊利诺伊大学香槟分校,材料科学与工程系,访问学者, 合作导师:Paul V. Braun

32013-09 2017-12,长春理工大学,化学与环境工程学院,讲师

() 主要研究方向

本课题组以新型能源材料结构设计与性能优化为核心切入点,聚焦水系锌离子电池、锂离子电池等主流储能体系,同时拓展锌碘电池、锂硫电池等高性能二次电池的前沿研发。通过精准构筑微纳结构电极材料、功能化多孔聚合物材料及有机 / 无机复合体系,系统开展电极材料的结构调控与性能优化,深入探究锌离子 / 锂离子存储机制及多电子反应动力学,旨在研制兼具高比容量、超长循环稳定性与优异倍率性能的新型二次电池,为大规模储能及便携电子设备提供高效、安全的能源解决方案。

主要研究方向

1.新型聚合物固体电解质的合成及性能研究

2.有机/无机复合多孔电极材料的构筑及储能机制研究

3.无机新能源材料的纳微结构设计、制备及储能机理研究

() 主要教学工作

  1. 本科生课程:无机化学、应用电化学、无机化学实验、应用化学专业实验

  2. 研究生课程:化学电源概论

  3. 教研项目:吉林省高等教育教学改革研究课题,2025-10,在研,主持。

二、主要学术成果

() 科研项目

  1. 吉林省科学技术厅, 吉林省自然科学基金面上项目, -碘电池正极用多孔聚合物的制备与性能研究,2024-01 2026-12, 12万元, 在研, 主持;

  2. 国家自然科学基金委员会, 面上项目,手性纳米孔道内有机小分子催化极性单体聚合:立构选择性调控与机制, 2021-01-01 2024-12-31, 63万元, 在研, 子课题主持

  3. 吉林省教育厅, 吉林省教育厅科学技术项目重点项目, 膜保护的三维多孔结构锌金属负极的原位构筑及性能研究, 2023-01 2024-12, 5万元, 结题,主持;

  4. 吉林省科学技术厅, 吉林省自然科学基金, 水系二次电池用三维多孔锌负极的结构设计、表界面调控及电化学性能研究, 2020-01 2022-12, 6万元, 结题, 主持;

  5. 吉林省教育厅, 吉林省教育厅十三五科学技术项目, 锰基三维双连续微纳结构复合电极材料的可控制备及性能研究, 2019-01 2020-12, 2.5万元, 结题, 主持;

  6. 吉林省教育厅十三五科学技术研究重点项目,纳米多孔金属氧化物复合材料的制备及在高性能锂离子电池中的应用,2016-012017-125万元结题,主持;

  7. 长春理工大学青年基金项目,骨固定用镁基准晶/聚乳酸复合材料的制备及性能研究,2014-10-2016-125万元结题,主持;

  8. 国家自然科学基金委员会, 青年科学基金项目, 导电各向异性光控可调Janus纳米带阵列膜的构筑及性质研究, 2019-01-01 2021-12-31, 27万元, 结题, 参与;

  9. 国家自然科学基金委员会, 青年科学基金项目, 一维嵌套结构柔性纳米材料的设计、构筑及光磁性能研究, 2019-01-01 2021-12-31, 24万元, 结题, 参与;

  10. 国家自然科学基金委员会,青年科学基金项目,新型分级结构氧化钨()-石墨烯复合纳米材料的可控制备及在气敏传感器上的应用研究,2017-01-012019-12-3124万元,结题,参与

() 专利及获奖

  1. 王昕璐; 李高鹏; 吕术慧; 王进贤; 于文生; 董相廷; 王天奇; 马千里; 李丹; 张洪波 ; 一种碳包覆的钒氧化物纳米点正极材料的制备方法与应用, 2022-11-18, 中国, CN202211442366.5 (专利)

  2. 王昕璐; 李高鹏; 王进贤; 刘东涛; 于文生; 董相廷; 杨颖; 王婷婷; 刘桂霞; 王天奇 ; 膜保护的三维多孔锌负极及其制备方法与应用, 2024-7-19, 中国, ZL202211366574.1 (专利)

  3. 董相廷; 李娇蕊; 于文生; 马千里; 王进贤; 王昕璐; 杨颖; 刘桂霞 ; 电磁发光光催化四功能两层纳米纤维复合膜及其制备方法, 2019-7-26, 中国, ZL201610765905.7 (专利)

  4. 董相廷; 王姿娇; 于文生; 马千里; 王进贤; 王昕璐; 于辉; 刘桂霞 ; 红色发光电磁三功能两层复合纳米纤维膜及其制备方法, 2018-10-23, 中国, ZL201610765900.4 (专利)

  5. 王昕璐(3/4); Ti基准晶复相材料电化学储氢特性的研究, 吉林省科技厅, 吉林省自然科学奖, 三等奖, 2019(刘万强; 王清爽; 王昕璐; 侯建华).

  6. 王昕璐(5/11); 低维纳米结构锂离子电池电极材料合成技术, 吉林省科技厅, 吉林省技术发明奖, 二等奖, 2016(王进贤; 于文生; 刘桂霞; 董相廷; 王昕璐; 宋超; 张洪波; 杨颖; 王婷婷; 马千里; 杨铭).

() 近期代表性论文

  1. Xinlu Wang* et. al. Amidoxime-functionalized hydrogel electrolyte enables dendrite-free and shuttle-free zinc-iodine batteries[J]. Journal of Energy Chemistry, 2026, 114: 536–545. https://doi.org/10.1016/j.jechem.2025.10.021.SCI 一区 TopIF=14.9

  2. Xinlu Wang* et. al. Highly stable composite polymer electrolyte with covalent/non-covalent network for solid-state zinc-iodine battery[J]. Energy Storage Materials, 2026, 86: 105023. https://doi.org/10.1016/j.ensm.2026.105023.SCI 一区 TopIF=20.2

  3. Xinlu Wang* et. al. Ultra-stable solid-state zinc-iodine battery enabled by a synergistic combination of self-crosslinked PIM and cyclodextrin[J]. Energy Storage Materials, 2025, 83: 104699. https://doi.org/10.1016/j.ensm.2025.104699.SCI 一区 TopIF=20.2

  4. Xinlu Wang* et. al. Iodine-confined porous covalent triazine frameworks enable ultra-stable aqueous zinc-iodine batteries[J]. Chemical Engineering Journal, 2025, 524: 169752. https://doi.org/10.1016/j.cej.2025.169752.SCI 一区 TopIF=13.2

  5. Xinlu Wang* et. Al. In-Situ Constructing a Film-coated 3D porous Zn anode by iodine etching strategy towards horizontally arranged dendrite-free Zn deposition. Advanced Functional Materials 33 (2023) 2208288. SCI一区TopIF = 19.924

  6. Xinlu Wang* et. Al. Construction of 3D porous zinc anode coated with FCTF protective layer through in-situ iodine etching strategy to enable highly stable zinc battery, Chemical Engineering Journal 496 (2024) 154367. SCI一区TopIF = 13.4

  7. Xinlu Wang* et. Al. The etching strategy of zinc anode to enable high performance zinc-ion batteries. Journal of Energy Chemistry, 88 (2024) 125-143. SCI 一区Top, IF = 13.1

  8. Xinlu Wang* et. al. From 0D to 3D: Controllable synthesis of ammonium vanadate materials for Zn2+ storage with superior rate performance and cycling stability. Chemical Engineering Journal 469 (2023) 143816. IF = 15.1, SCI 一区Top

  9. Xinlu Wang* et. al. Long-life and low-polarization Zn metal anodes enabled by a covalent triazine framework coating. Chemical Engineering Journal 450 (2022) 138116. IF = 16.744, SCI一区Top

  10. Xinlu Wang* et. al. A specific free-volume network as synergistic zinc–ion–conductor interface towards stable zinc anode. Energy Storage Materials 53 (2022) 909–916. IF = 20.831, SCI一区Top

  11. Xinlu Wang* et. al. Construction of porous phenolphthalein-based polymer coating to enable highly stable zinc metal anodes. Rare Metals, 2025, doi.org/10.1007/s12598-025-03386-9. SCI一区, IF = 11

  12. Xinlu Wang* et. al. Hollow nanofiber ion conductor protective layer on Zn metal anode for long-term stable zinc battery[J]. Journal of Energy Storage, 2026, 146: 120281. https://doi.org/10.1016/j.est.2025.120281.SCI 二区,IF=8.9

  13. Xinlu Wang* et. al. In situ constructing film-coated 3D porous Zn anodes by redox strategy toward dendrite-free aqueous zinc-ion batteries[J]. Materials Today Chemistry, 2026, 52: 103445. https://doi.org/10.1016/j.mtchem.2026.103445.SCI 二区,IF=6.7

  14. Xinlu Wang* et. al. Recent advances of manganese-based cathodes for aqueous zinc-ion batteries[J]. Materials Today Chemistry, 2026, 52: 103370. https://doi.org/10.1016/j.mtchem.2026.103370.SCI 二区,IF=6.7

  15. Xinlu Wang* et. al. Ca2+-intercalation improving the electrochemical cyclicity of the ammonium vanadate cathode for aqueous zinc-ion batteries. Electrochimica Acta 527 (2025) 146277. https://doi.org/10.1016/j.electacta.2025.146277.SCI,IF = 5.6

  16. Xinlu Wang* et. al, Constructing 3D zinc anode by acid etching strategy toward long-cycling aqueous Zinc-ion batteries. Electrochimica Acta 536 (2025) 146800. https://doi.org/10.1016/j.electacta.2025.146800.SCI, IF = 5.6

  17. Xinlu Wang* et. al, Synergistic sodium-ion and poly (3,4-ethylenedioxythiophene) Co-intercalation in ammonium vanadate: Realizing ultra-stable and high-performance aqueous zinc-ion batteries. Journal of Power Sources 641 (2025) 236830. https://doi.org/10.1016/j.jpowsour.2025.236830.SCI三区, IF = 8.1

  18. Xinlu Wang* et. al, In-situ micro-battery etching induced 3D Zn with amorphous interfacial coating for high-stable Zn metal batteries. Journal of Energy Storage 106 (2025) 114853. https://doi.org/10.1016/j.est.2024.114853.SCI二区, IF = 8.9

  19. Xinlu Wang* et. al, Dendrite-free and highly stable Zn metal anode enabled by fluorinated covalent triazine framework coating. Journal of Power Sources 613 (2024) 234876. https://doi.org/10.1016/j.jpowsour.2024.234876.SCI二区Top, IF = 8.1

  20. Xinlu Wang* et. al, A porous polycaprolactone coating with abundant ester groups for stable Zn metal anodes. Journal of Energy Storage 97 (2024) 112790. https://doi.org/10.1016/j.est.2024.112790.SCI二区, IF = 8.9

  21. Xinlu Wang* et. al, Rational design of polymer electrolytes with three-dimensional cyclodextrin-based covalent organic framework for lithium-iodine batteries, Journal of Energy Storage, 84 (2024) 110820. https://doi.org/10.1016/j.est.2024.110820.SCI二区, IF = 8.9

  22. Xinlu Wang* et. al, One-Pot preparation of microporous-polymer protected 3D porous Zn anode to enable advanced aqueous zinc batteries, Journal of Power Sources, 589 (2024) 233755. https://doi.org/10.1016/j.jpowsour.2023.233755.SCI二区, IF = 8.1

  23. Xinlu Wang* et. al, Zincophilic polyurethane-based porous film enables dendrite-free zinc anode for reversible aqueous zinc-based batteries, Colloid and Surface A 661 (2023) 130960. https://doi.org/10.1016/j.colsurfa.2023.130960.SCI二区, IF = 4.494

  24. Xinlu Wang* et. al, Recent advances of organic polymers for zinc-ion batteries. Sustainable Energy Fuels 6 (2022) 5439–5458. https://doi.org/10.1039/d2se01398c.SCI三区, IF = 6.813

  25. Xinlu Wang* et. al, The strategies of boosting highly reversible zinc anodes in zinc ion batteries: Recent progress and future perspectives. Sustainable Energy Fuels 5 (2021) 332. https://doi.org/10.1039/d0se01508cSCI三区, IF = 6.813

  26. Xinlu Wang* et. al, Controllable synthesis of nanostructured ZnCo2O4 as high-performance anode materials for lithiumion batteries. RSC Advances, 8 (2018) 39377–39383. IF = 4.036, SCI三区)

  27. Xinlu Wang* et. al, Facile Synthesis of Fe3O4/NiFe2O4 Nanosheets With Enhanced Lithium-ion Storage by One-step Chemical Dealloying. Journal of Materials Science, 53 (2018) 15631–15642. IF = 4.682, SCI二区)

  28. Xinlu Wang* et. al, Hierarchical porous CoNi/CoO/NiO composites derived from dealloyed quasicrystals as advanced anodes for lithium-ion batteries. Scripta Materialia, 139 (2017) 30–33. IF = 6.302, SCI二区)

  29. Xinlu Wang* et. al, High Electrochemical Performance of Nanoporous Fe3O4/CuO/Cu Composites Synthesized by Dealloying Al-Cu-Fe Quasicrystal. Journal of Alloys and Compounds, 729 (2017) 360–369. IF = 6.371, SCI二区)

  30. Xinlu Wang* et. al, Nanostructured CoO/NiO/CoNi Anodes with Tunable Morphology for High Performance Lithium-ion Batteries. Dalton transactions, 46 (2017) 11031–11036. IF = 4.569, SCI二区)

  31. Xinlu Wang* et. al, Electrospun Li3V2(PO4)3 Nanobelts: Synthesis and Electrochemical Properties as Cathode Materials of Lithium-ion Batteries. Journal of The Chinese Chemical Society, 64 (2017) 557–564. IF = 1.753, SCI四区)

  32. Xinlu Wang* et. al, Fabrication of Ce2S3/MoS2 Composites via Recrystallization-Sulfurization Method and Their Improved Electrochemical Performance for Lithium-ion Batteries. Journal of materials science-materials in electronics, 28 (2017) 12297–12305. IF = 2.324, SCI三区)

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