姓名：张萌

职称：讲师

职位：无

邮箱：MengZhang@nbut.edu.cn

办公室：前湾校区新能源产业技术创新实践基地 414 室

研究方向：有机储能材料的研发及性能探究

个人简介：

张萌，女，1996年出生，中共党员，工学博士，讲师，宁波工程学院新能源学院教师。长期从事有机电极材料的设计、制备、储能性能及反应机理研究。致力于从分子结构设计角度出发，构建共轭羰基化合物、共轭微孔聚合物（CMP）和共价有机框架（COF），全面提升二次电池的综合电化学性能。

教育背景：

2014.09-2018.06   江西科技师范大学    应用化学             理学学士

2018.09-2024.06   燕山大学         化学工程与技术专业      工学博士（硕博连读）

工作经历：

2024.09-至今    宁波工程学院     讲师

项目：

[1]. 河北省自然科学基金（No. B2019203487）：通用型高容量Li/Na正极材料TC4Q的合成及其固态电池的构筑，参与

[2]. 河北省博士研究生创新资助项目（CXZZBS2022144）：硫杂环羰基化合物的合成及其储钠性能研究，承担

[3]. 河北省硕士研究生创新资助项目：高容量锂正极材料C8Q及其固态电池的构筑项目，参与

[4]. 先进能源材料化学教育部重点实验室（南开大学）2018年度开放基金：通用型高容量Li/Na正极材料TC4Q的合成及其固态电池的构筑，参与

代表性论文：

[1] Zhang M, Tong Y, Sun Z, Wang J, Lin Y, Kang F, Zhang Q*, Huang W*.Two-dimensional covalent organic framework with synergistic active centers for efficient electrochemical sodium storage.Chemistry of Materials, 2023, 35, 4873-4881.

[2] Zhang M, Zhou W, Huang W*. Characterization methods of organic electrode materials. Journal of Energy Chemistry, 2021, 57, 291-303.

[3] Zhang M, Lin Y, Huang W*. Synthesis, Characterization and electrochemical lithium-ion storage property of sulfonylcalix[4]quinone. Inorganic Chemistry Frontiers, 2023, 10, 6738-6745.

[4] Zhang M, Ding C, Li C, Wang Y, Huang W*. Bioactive small molecule based aqueous zinc-organic battery enables long-life and fast-charge performance. Science China Materials, 2023, 66, 3104-3112.

[5] Zhang M, Tong Y, Xie J, Huang W*, Zhang Q*. Rechargeable sodium-ion battery based on polyazaacene analogue anode. Chemistry-A European Journal, 2021, 27, 16754-16759.

[6] Zhang M, Zhang Y, Huang W*, Zhang Q*. Recent progress in calix[n]quinone (n=4, 6) and pillar[5]quinone electrodes for secondary rechargeable batteries. Batteries & Supercaps, 2020, 3, 476-487.

[7] Huang W^1,*, Zhang M¹, Cui H, Yan B, Liu Y, Zhang Q*. Cost-effective biomass carbon/calix[4]quinone composites for lithium ion batteries. Chemistry-An Asian Journal, 2019, 14, 4164-4168.

[8] Zhou W, Zhang M, Kong X, Huang W*, Zhang Q*. Recent advance in ionic liquids-based electrolytes for rechargeable metal-ion batteries. Advanced Science, 2021, 8, 2004490.

[9] Su J, Zhang M, Tian H, Han M, Sun Z, Du K, Cui F, Li J, Huang W*, Hu Y*. Synergistic π-conjugation organic cathode for ultra-stable aqueous aluminum batteries. Small, 2024, 20, 2312086.

[10] Han M, Zhou Q, Zhang M, Wang J, Cui F, Yang Y, Su J, Huang W*, Hu Y*. Rotatable cathode with tunable steric hindrance for high-performance aluminum organic batteries. Journal of Materials Chemistry A, 2023, 11, 13527-13534.

[11] Xiong W, Huang W*, Zhang M, Hu P, Cui H, Zhang Q*. Pillar[5]quinone-carbon nanocomposites as high capacity cathodes for sodium-ion batteries. Chemistry of Materials, 2019, 31, 8069-8075.

[12] Zhang X, Zhou W, Zhang M, Yang Z, Huang W*. Superior performance for lithium-ion battery with organic cathode and ionic liquid electrolyte. Journal of Energy Chemistry, 2021, 52, 28-32.

[13] Sun Z, Tian H, Zhang M, Zhang Y, Li Z, Huang W*. Insights into the modulation mechanisms of multiple active sites in a conjugated small-molecule for organic cathodes capacity from first-principles. Inorganic Chemistry Frontiers, 2024, 11, 2957-2964.

[14] Sun Z, Liu L, Zhang M, Huang W*. Quantitative analysis of molecular surface: systematic application on sodiation mechanism of benzoquinone-based pillared compound as cathode. Inorganic Chemistry Frontiers, 2022, 9, 3412-3420.