姓名：王宁珍

职称：副教授

学科：车辆工程

E-mail：ningzhenwang@bjfu.edu.cn

研究方向：

1.汽车构件的防撞吸能与轻量化

2.泡沫金属的制备及性能

3.电介质绝缘材料

4.柔性压电材料

5.人体可穿戴智能系统

导师类别：硕士生导师

招生方向：

机械工程硕士

欢迎具有材料加工、电气工程、机械工程和车辆工程等专业的考生报考，有兴趣者可通过邮箱联系

主讲课程：

材料力学、汽车技术新发展、汽车构造等

教育经历：

2013. 09 – 2018. 07 清华大学，博士

2017. 02 – 2017. 07 法国 里昂国立应用科学学院，访问学者

2009. 09 – 2013. 07 华中科技大学，学士

工作经历：

2023. 02 – 至今 北京林业大学工学院，副教授

2019. 12 – 2023. 02 美国 康涅狄格大学，博士后

2018. 09 – 2019. 08 德国 柏林工业大学，博士后

获奖及兼职：

•国家海外引才专项第二层次

•北京市2024–2026年度青年人才托举工程

•中国复合材料学会介电高分子复合材料及应用专委会委员

•中国物理学会静电专委会青年委员

•全国驻极体理论及应用研讨会学术委员会委员

•《铸造技术》期刊首届青年编委及优秀审稿人

•《机械工程材料》期刊首届青年编委

•北京市发明创新大赛铜奖

•担任Colloids Surf., A, Materialia, IEEE Trans DEI等多个期刊的审稿人

承担课题及主要成果：

主持国家自然科学基金、北京市自然科学基金、全国重点实验室开放基金、横向合作课题等多个项目，以第一或通讯作者在Advanced Materials，Advanced Functional Materials，Small等发表SCI论文多篇，获两项发明专利授权。

代表性论文成果：

[1]. N. Wang, H. Zhang, X. Qiu, R. Gerhard, J. van Turnhout, J. Cressotti, D. Zhao, L. Tang, Y. Cao, Recent Advances in Ferroelectret Fabrication, Performance Optimization and Applications. Advanced Materials, 2024, 2400657.

[2]. N. Wang, M. Zhu, R. Yang, S. Shang, P. Zhang, N. Chen, L. Tang, X. Chen. Cell size controlling of closed-cell aluminum foams. Journal of Materials Research and Technology, 2025, 36, 1294-1313.

[3]. N. Wang, R. Daniels, L. Connelly, M. Sotzing, C. Wu, R. Gerhard, G. A. Sotzing, Y. Cao, All-Organic Flexible Ferroelectret Nanogenerator with Fabric-Based Electrodes for Self-Powered Body Area Networks. Small, 2021, 17(33): 2103161. (封面报道)

[4]. N. Wang, J. van Turnhout, R. Daniels, C. Wu, J. Huo, R. Gerhard, G. Sotzing, Y. Cao. Ion-boosting the charge density and piezoelectric response of ferroelectrets to significantly high levels. ACS Applied Materials & Interfaces, 2022, 14(37): 42705-42712.

[5]. Z. Shi, P. He, N. Wang*, Y. Liu, X. Chen, Y. Li, G. Ding*, Q. Yu*, X. Xie*. Bubble mediated mass production of graphene: a review. Advanced Functional Materials, 2022, 2203124. (封面报道)

[6]. P. Zhang, H. Zhang, N. Chen, N. Wang*, C. Song, R. Yang, X. Chen*. A novel composite of Closed-Cell aluminum foam and Phase-Change material for enhanced mechanical safety in EV battery systems. Composite Structures, 2025, 119504.

[7]. N. Wang, E. Maire, X. Chen, J. Adrien, Y. Li, Y. Amani, L. Hu, Y. Cheng. Compressive performance and deformation mechanism of the dynamic gas injection aluminum foams. Materials Characterization, 2019, 147: 11-20.

[8]. N. Wang, E. Maire, Y. Cheng, Y. Amani, Y. Li, J. Adrien, X. Chen. Comparison of aluminium foams prepared by different methods using X-ray tomography. Materials Characterization, 2018, 138: 296-307.

[9]. N. Wang, X. Chen, A. Li, Y. Li, H. Zhang, Y. Liu. Three-point bending performance of a new aluminum foam composite structure. Transactions of Nonferrous Metals Society of China, 2016, 26(2): 359-368.

[10]. N. Wang, X. Chen, J. Yuan, G. Wang, Y. Li, H. Zhang, Y. Liu. Bubble formation at a submerged orifice in high-speed horizontal oscillation. Metallurgical and Materials Transactions B, 2016, 47(6): 3362-3374.

[11]. N. Wang, X. Chen, Y. Li, Z. Liu, Z. Zhao, Y. Cheng, Y. Liu, H. Zhang. The cell size reduction of aluminum foam with dynamic gas injection based on the improved foamable melt. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2017, 527: 123-131.

[12]. N. Wang, M. A. Baferani, R. Daniels, C. Wu, J. Huo, J. van Turnhout, G. A. Sotzing, R. Gerhard, Y. Cao. Macro-dipoles in soft/hard expanded-polytetrafluoroethylene+ fluoroethylenepropylene (ePTFE+ FEP) fluoropolymer-film systems for high-output piezoelectric ferroelectret-transducer applications. Journal of Physics D: Applied Physics, 2024, 57, 145502.

[13].N. Wang, M. A. Noack, P. H. Kamm, J. Banhart, F. García-Moreno. Short-range ordered aluminum foams. Advanced Engineering Materials, 2021, 24(3): 2100795.

[14].N. Wang, X. Chen, E. Maire, P. H. Kamm, Y. Cheng, Y. Li, F. García-Moreno. Study on Cell Deformation of Low Porosity Aluminum Foams under Quasi-Static Compression by X-Ray Tomography. Advanced Engineering Materials, 2020, 22(10): 2000264.

[15].M. Ploner†, N. Wang†, C. Wu, R. Daniels, G. A. Sotzing, Y. Cao*. Ultrathin, all-organic, fabric based ferroelectret loudspeaker for wearable electronics. iScience, 2022, 25(12), 105607.

[16].N. Wang, X. Chen, Y. Li, Y. Liu, H. Zhang, X. Wang. Preparation and compressive performance of an A356 matrix syntactic foam. Materials Transactions, 2018, 59(5): 699-705.

[17].X. Chen*, N. Wang, J. Yuan, Y. Li, H. Zhang, Y. Liu. Modelling of macro deformation behavior of thin-walled aluminum foam by gas injection method. Journal of Materials Engineering and Performance, 2017, 26(7): 3307-3318.

[18].N. Wang, R. Daniels, L. Connelly, J. Ronzello, G. A. Sotzing, Y. Cao. All-organic flexible ferroelectret nanogenerator for wearable electronics. 2020 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP), IEEE, 259-262.

[19].N. Wang, K. Davis, M. Sotzing, M. A. Baferani, J. Huo, C. Barry Carter, Reimund Gerhard, Yang Cao. Flexible nanogenerator with 3D-printed ferroelectrets. 2021 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP), IEEE, 375-378.

专利成果：

[1]. 陈祥; 王宁珍; 李言祥; 刘源; 张华伟 ; 吹气法制备泡沫铝装置及泡沫铝的制备方法, 2016-11-23, 中国, ZL201610552868.1

[2]. 陈祥; 王宁珍; 李言祥; 刘源; 张华伟 ; 一种金属基空心球复合泡沫材料及其制备方法, 2018-9-4, 中国, ZL201810167127.0