还献华  工学博士 · 硕士生导师

电子邮件：huanxianhua@hfut.edu.cn

通讯地址：安徽省合肥市包河区屯溪路193号合肥工业大学逸夫楼

【教育及工作背景】

▸ 2012-2022  北京化工大学 · 材料科学与工程（本科、博士）

▸ 2022-至今  合肥工业大学 · 电气与自动化工程学院 · 高电压与绝缘技术实验室 · 讲师

【研究方向】

▸ 电气绝缘材料

▸ 功能电介质材料

▸ 复合材料回收再利用

【科研项目及荣誉】

▸ 主持国家自然科学基金青年基金项目，国家科技重大专项课题子任务，科技部国家重点研发计划项目课题子任务，国家电网公司、南方电网公司等重大企业攻关项目等

▸ 入选中国复合材料学会青年人才托举工程

【学生培养】

硕士研究生：

  · 胡冰冰（2023级，首届研究生）— 国家奖学金，毕业去向 常州博瑞电力自动化设备有限公司

  · 臧泓（2023级，协助指导）— 毕业去向 国网山东省电力公司潍坊市局

本科生（部分）：

  · 王子豪（2021级）— 优秀本科毕设论文，赴同济大学读研

  · 杨恭庆（2021级）— 赴哈尔滨工业大学读研

  · 叶英晗（2022级）— 赴西安交通大学读研

  · 吴泊宸（2022级）— 以第二申请人授权发明专利1篇（导师第一），合肥工业大学电力电子方向读研

【论文及专著】

参编专著：

  · “十四五”战略性新兴领域高等教育系列教材《高端装备构造原理》

  · “十三五”国家重点出版物出版规划项目《先进复合材料系列丛书》复合材料回收再利用分册

已发表学术论文（部分摘录）：

2026

[1]      Liu, S., Shen, C., Deng Z., Huan, X. *, et al. Non-Equilibrium Pyrolysis Enables Nano-Confined Hetero-Interfaces in MOF-Derivatives for Advanced Dielectric Engineering. Advanced Functional Materials, 2026, e75267. （中科院一区，与复旦大学合作发表）

[2]      Wu, Z.*, Wang, J., Guo, W., Zhao, J., Huan, X.*, Ma, R., & Zhang, Q. Reconstructing surface aggregation state of aramid fiber via plasma towards efficient interfacial engineering of composites. Composites Part B: Engineering, 2026, 113635. （中科院一区，与西安交通大学合作发表）

2025

[1]       Huan, X., Liu, S., Zhou, E., et al. Multi-Stimuli-Responsive Dielectric Composites: Composition–Structure–Nanoscale Mechanism–Function Framework for Dynamic Dielectric Engineering. Advanced Functional Materials, 2025, e21845.（中科院一区，与复旦大学合作发表）

[2]       Huan, X., Zang, H., Du, B., et al. Reaction Condition-Driven Structural Evolution during Epoxy Resin Chain Extension and Its Influence on Insulator Material Properties. Journal of Applied Polymer Science, 2025, 143(8), e70086.

[3]       Huan, X., Hu, B., Zang, H., Ji, Z., Gao, C., Zhou, F., ... & Zhao, Y. Building Block Orchestration Enables Efficient and Uniform Curing for Tough and Highly Insulating Epoxy. ACS Applied Polymer Materials, 2025, 7(13): 8766–8775.（封面论文）

[4]       Huan, X., Hu, B., Ji, Z., Gao, C., Zhou, F., Yu, J., ... & Zhao, Y. Enhancing Electrical Insulation of Epoxy Composites by Suppressing Charge Injection and Subsequently Electric Field Distortion. Composites Communications, 2025, 56, 102391.

[5]       Zhu, J., Li, H., Yi, J., Chen, Z., Ge, L., Liu, C., Geng, H., Chen, X., Li, T., Deng, D., & Huan, X.* Electromagnetic Techniques in Carbon Fibre and Carbon Fibre Composites Manufacturing: A Review. Composites Part B: Engineering, 2025, 112227.（中科院一区，与澳大利亚南昆士兰大学合作发表）

[6]       Wu, Z.*, Zhu, Q., Ai, Z., Bu, Q., Ma, R., Zhang, Z., Xu, C., Huan, X.*, & Zhang, Q. Tailored Interfacial sp2/sp3 Hybridization in Diamond@DLC Heterostructure: Resolving the Microwave Absorption–Dielectric–Thermal Trilemma in Epoxy Composites for Electronic Packaging. ACS Applied Materials & Interfaces, 2025, 17(47), 64853-64863.（与西安交通大学合作发表）

[7]       Zhao, Y., Zhao, Y., Shen, H., Huan, X.*, Du, B.*, Chen, Q., & Zheng, Y. Construction of Multilevel Molecular Chain Epoxy Crosslinking Network for Synergistic Improvement of Insulation and Mechanical Properties of Materials. IEEE Transactions on Dielectrics and Electrical Insulation, 2025.

[8]       Zheng, Y., Gao, C., Zhou, F., Wang, G., Zang, H., Ji, Z., & Huan, X. Catalyst-driven optimization of epoxy curing: enhanced mechanical, thermal, and electrical insulation performance. Materials Letters, 2025, 138694.（与南方电网科学研究院合作发表）

2024

[1]       Li, Y., Li, H., Dong, J., Chen, Z., Zhao, J., Huan, X.*, et al. Revisiting the Sequential Evolution of Sizing Agents in CFRP Manufacturing to Guide Cross-Scale Synergistic Optimization of Interphase Gradient and Infiltration. Composites Part B: Engineering, 2024, 111825.（中科院一区，与北京化工大学合作发表）

[2]       Du, B., An, Y., Huan, X.*, Yang, L., & Zhao, Y. MWCNTs/C60 “Grape-like” Nanostructures for Enhancing Piezoelectric Performance in PVDF Nanofibers through Constructing Localized Conductive Domains. ACS Applied Electronic Materials, 2024, 7(1): 104–114.

[3]       Wu, Z., Ma, R., Ai, Z., Huan, X., Wang, S., Fan, W., & Zhang, Q. In situ interfacial evaluation of aramid/epoxy composites by interfacial stress transfer characteristics. Review of Scientific Instruments, 2024, 95(7). （与西安交通大学合作发表）

2023

[1]       Huan, X., Li, H., Song, Y., et al. Charge Dynamics Engineering Sparks Hetero-Interfacial Polarization for an Ultra-Efficient Microwave Absorber with Mechanical Robustness. Small, 2023, 2306104.（封面论文）

[2]       Du, B., Zhang, G., Huan, X.*, et al. Electrostatically Self-Assembled Fe₃O₄@SiO₂/MXene 3D Interlayered Structure Improves Ku-band Microwave Absorption Efficiency of Epoxy-Based Nanocomposites. Composites Part A: Applied Science and Manufacturing, 2024, 177: 107956.

[3]       Wu, T., Huan, X., Zhang, H., et al. Orientation and Inhomogeneous Distribution of Carbon Nanofibers and Distinctive Internal Structure in Polymer Composites Induced by 3D Printing Enabling Electromagnetic Shielding Regulation. Journal of Colloid and Interface Science, 2023, 638: 392–402.（中科院一区）

[4]       Liu, C., Li, H., Huan, X., et al. Confining Fluorescence Detection for Distinguishable Visualization of Multivariate Nanoparticles: Implications for Design and Controllable Preparation of Nanocomposites. ACS Applied Nano Materials, 2023, 6(7): 5233–5241.

2022及以前

[1]       Huan, X., Wang, H., Deng, W., et al. Integrating Multi-Heterointerfaces in a 1D@2D@1D Hierarchical Structure via Autocatalytic Pyrolysis for Ultra-Efficient Microwave Absorption Performance. Small, 2022, 18(13): 2105411.（ESI高被引；封面论文）

[2]       Wu, T., Huan, X., Jia, X., et al. 3D Printing Nanocomposites with Enhanced Mechanical Property and Excellent Electromagnetic Wave Absorption Capability via ZIF-Derivative Modified Carbon Fibers. Composites Part B: Engineering, 2022, 233: 109658.（中科院一区）

[3]       Huan, X., Wu, T., Yan, J., et al. Phosphoric Acid-Derived Efficient Reclamation of Carbon Fibre for Re-Manufacturing High-Performance Epoxy Composites Reinforced by Highly-Aligned Mat with Optimized Layup. Composites Part B: Engineering, 2021, 211: 108656.（中科院一区）

[4]       Liu, C., Meng, L., Huan, X., et al. In Situ Characterization of Macroscale 3D Spatial Dispersion of MWCNTs in Matrix and Interfacial Phases of Quartz Fibers/Epoxy Composites via Fluorescence Imaging. Journal of Materials Science, 2021, 56: 16399–16421.

[5]       Huan, X., Shi, K., Yan, J., et al. High-Performance Epoxy Composites Prepared Using Recycled Short Carbon Fiber with Enhanced Dispersibility and Interfacial Bonding through Polydopamine Surface Modification. Composites Part B: Engineering, 2020, 193: 107987.（中科院一区）

[6]       Fu, P., Huan, X., Luo, J., et al. Magnetically Aligned Fe₃O₄ Nanowires–Reduced Graphene Oxide for Gas Barrier, Microwave Absorption, and EMI Shielding. ACS Applied Nano Materials, 2020, 3(9): 9340–9355.

[7]       Shi, K., Luo, J., Huan, X., et al. Ionic Liquid–Graphene Oxide for Strengthening Microwave-Curing Epoxy Composites. ACS Applied Nano Materials, 2020, 3(12): 11955–11969.