韩兵

韩博士长期致力于利用多维度冷冻电镜技术研究器件界面的物理新机制并实现器件调控和优化的研究。针对半导体材料及界面电子束辐照损伤的问题，采用了超低剂量冷冻电镜技术，实现了晶界缺陷精准成像，揭示了钙钛矿晶界相干性的微观新机制，并以此为基础提出了提升器件性能的界面工艺调控策略。另外，针对离子型器件的空间相分析极易遭受电子束辐射损伤的难题，通过对电子束剂量的精准调控，开创性地实现了离子器件界面层的原子级成像、电子能量损失谱分布及三维结构演化。

研究领域涉及超低剂量冷冻电镜成像技术；器件界面的失效分析；人工智能赋能多维图像解析；材料低温加工与表征；电子显微学中的光学问题；微纳米器件加工与图形化；敏感电子学；光谱信息（电子能量损失谱等）获取与处理

2025年-至今，宁波东方理工大学工学部，副教授，研究员

2024年-2025年，香港理工大学，博士后研究员

2022年-2023年，美国阿贡国家实验室，科学家

2021年-2024年，加州大学圣地亚哥分校纳米工程系，博士后研究员

迄今，申请人共发表SCI论文70余篇，其中以第一/通讯作者（含共同）在Nature（1）、Science（1）、Nature Communication（3）、Advanced Materials（8）、Energy & Environmental Science、Journal of the American Chemical Society（2）等期刊发表论文30余篇，已授权国家专利和美国专利30余项。

论文总被引5000余次，H因子为36；

Google Scholar：

https://scholar.google.com/citations?hl=en&user=jPkd4U4AAAAJ

代表作（*表示通讯作者）

Journal Publications (Han B. is Bing Han)

2025, 2024, 2023

1.Li, S., Xiao, Y., Su, R., Xu, W., Luo, D. *, …Han, B. * (corresponding author), ... & Zhu, R. * (2024). Coherent growth of high-Miller-index facets enhances perovskite solar cells. Nature, 1-3.

2.Yao Li, …Han, B. * (corresponding author), ... (2024). Temperature-Adaptive Fluorine in Electrolyte for Lithium–Metal Batteries at Low Temperatures. ACS Energy Letters, 7(10) 3610-3619.

3.Hong, H., Wang, Y., Zhang, Y., Han, B. * (corresponding author), Li, Q., Guo, X., ... & Zhi, C. * (2024). Hydrogen‐Bonded Ionic Co‐Crystals for Fast Solid‐State Zinc Ion Storage. Advanced Materials, 36(47), 2407150.

4.You S.#,…Han B.# (co-first author), … & Li, X. (2023). Radical polymeric p-doping and grain modulation for stable, efficient perovskite solar modules. Science, 379(6629), 288-294.

5.Xiu, J. #, Han, B. #(co-first author),... & He, Z. (2023). A Sustainable Approach Using Nanocrystals Functionalized Green Alkanes as Efficient Antisolvents to Fabricate High‐Quality Perovskite Films. Advanced Energy Materials, 2300566.

6.Shu, L. #, Han, B. #(co-first author), ... & Fan, Z. (2023). Highly Efficient Blue Light‐Emitting Diodes Based on Perovskite Film with Vertically Graded Bandgap and Organic Grain Boundary Passivation Shells. Advanced Functional Materials, 33(46), 2306570.

7.Cheng, D., …., Han, B., & Meng, Y. S. (2023). A free-standing lithium phosphorus oxynitride thin film electrolyte promotes uniformly dense lithium metal deposition with no external pressure. Nature Nanotechnology, 1-8.

8.Liang, G., Tang, Z., Han, B. * (corresponding author), Zhu, J., Chen, A., Li, Q., ... & Zhi, C. (2023). Regulating Inorganic and Organic Components to Build Amorphous‐ZnFx Enriched Solid‐electrolyte Interphase for Highly Reversible Zn Metal Chemistry. Advanced Materials, 2210051.

9.Biao, J., Han, B. (co-first author), Cao, Y., Li, Q., Zhong, G., Ma, J., ... & He, Y. B. (2023). Inhibiting Formation and Reduction of Li2CO3 to LiCx at Grain Boundaries in Garnet Electrolytes to Prevent Li Penetration. Advanced Materials, 2208951.

2022

10.Han B, X Li, Y Deng. Cryo-Electron Tomography of Highly Deformable and Adherent Solid-Electrolyte Interphase Exoskeleton in Li-Metal Batteries with Ether-based Electrolyte, Advanced materials (Deerfield Beach, Fla.), (2022) e2108252.

11.Ke, R., Du, L., Han, B. * (co-first author and corresponding author), Xu, H., Meng, H., Zeng, H., ... & Deng, Y. (2022). Biobased Self-Growing Approach toward Tailored, Integrated High-Performance Flexible Lithium-Ion Battery. Nano Letters, 22(23), 9327-9334.

12.Zhang P.#, Han B.#* (co-first author and corresponding author), Francisco J.*, Gu, M.* (2022). Revealing the Intrinsic Atomic Structure and Chemistry of Amorphous LiO2-Containing Products in Li–O2 Batteries Using Cryogenic Electron Microscopy. Journal of the American Chemical Society, 144, 5, 2129–2136.

13.Li S., Wang X., Han B. (co-first author), et al. Ultrathin and High‐Modulus LiBO2 Layer Highly Elevates the Interfacial Dynamics and Stability of Lithium Anode under Wide Temperature Range[J]. Small, 2021: 2106427.

2021

14.Han B, Li X, Bai S, et al. Conformal Three-Dimensional Interphase of Li Metal Anode Revealed by Low Dose Cryo-Electron Microscopy[J]. Matter, 2021, Accepted.

15.Han B, Zou Y, Xu G, et al. Additive stabilization of SEI on graphite observed using cryo-electron microscopy[J]. Energy & Environmental Science, 2021, 14(9): 4882-4889.

16.Han, B., Zou, Y., Zhang, Z. et al. (2021). Probing the Na metal solid electrolyte interphase via cryo-transmission electron microscopy. Nature Communication, 12, 3066.

17.Han, B., Zhang, Z., Zou, Y., Xu, K., Xu, G., Wang, H., ... & Gu, M. (2021). Poor Stability of Li2CO3 in the Solid Electrolyte Interphase of a Lithium-Metal Anode Revealed by Cryo-Electron Microscopy. Advanced Materials, 2100404.

18.Han, B., Zou, Y., Ke, R., Li, T., ... & Meng, H. (2021). Stable Lithium Metal Anodes with a GaOx Artificial Solid Electrolyte Interphase in Damp Air. ACS Applied Materials & Interfaces, 13, 18, 21467–21473

19.Zhang Q, Han B* (co-first author and corresponding author), Zou Y, et al. Enabling Atomic‐Scale Imaging of Sensitive Potassium Metal and Related Solid Electrolyte Interphases Using Ultralow‐Dose Cryo‐TEM[J]. Advanced Materials, 2021, 33(43): 2102666.

20.Li X, Han B* (co-first author and corresponding author), Yang X, et al. Three-Dimensional Visualization of Lithium Metal Anode via Low-Dose Cryogenic Electron Microscopy Tomography[J]. iScience, 2021: 103418.

21.Chen, W., Han, B. (co-first author), Hu, Q., Gu, M., Zhu, Y., ... & Russell, T. (2021). Interfacial stabilization for inverted perovskite solar cells with long-term stability, Science Bulletin, 66, 991–10.

22.Liu F, Qin X, Han B*(corresponding author), et al. Enhanced Light Emission Performance of Mixed Cation Perovskite Films—The Effect of Solution Stoichiometry on Crystallization[J]. Advanced Optical Materials, 2021, 9(21): 2100393.

2020

23.Han, B., Xu, D., Chi, S. S., He, D., Zhang, Z., Du, L. & Deng, Y. (2020). 500 Wh kg− 1 Class Li Metal Battery Enabled by a Self‐Organized Core–Shell Composite Anode. Advanced Materials, 32(42), 2004793.

24.Han, B., Feng, D., Li, S., Zhang, Z., Zou, Y., Gu, M., ... & Deng, Y. (2020). Self-regulated phenomenon of inorganic artificial solid electrolyte interphase for lithium metal batteries. Nano letters, 20(5), 4029-4037.

25.Xiao, Y., Han, B.(co-first author), Zeng, Y., Chi, S. S., Zeng, X., Zheng, Z., ... & Deng, Y. (2020). New lithium salt forms interphases suppressing both Li dendrite and polysulfide shuttling. Advanced Energy Materials, 10(14), 1903937.

2013-2019 

26.Han, B., Yang, Y., Shi, X., Zhang, G., Gong, L., Xu, D., Deng, Y. (2018). Spontaneous repairing liquid metal/Si nanocomposite as a smart conductive-additive-free anode for lithium-ion battery. Nano energy, 50, 359-366.

27.Xian Z.; Han B. (co-first author); Kempa K.*, Gao J.* A Practical ITO Replacement Strategy: Sputtering-Free Processing of a Metallic Nanonetwork. Advanced Materials Technologies, DOI: 10.1002/admt. 201700061.

28.Han, B., Peng Q., Li R., Rong Q., Kempa K.* Gao J.*, Optimization of hierarchical structure andnanoscale-enabled plasmonic refraction for windowelectrodes in photovoltaics. Nature Communications 2016 03:01:14,10.1038/ncomms12825.

29.Gao J.*, Kempa K.*, Giersig M.*, Akinoglu E., Han B., Li R., Physics of Transparent Conductors. Advanced in Physics 2016,6, 553–617. 

30.Han, B., Huang Y.; Li R.; Peng Q.; Luo J.; Pei K.; Herczynski A.; Kempa K.; Ren Z., Gao J., Bio-inspired Networks for Optoelectronic Applications. Nature Communications 2014, 5: 5674, 10.1038/ncomm6674. (News: Science daily, Phys.org, Eurek.org, Asiaeu.com, Newsgb.com, Topix.com, Lockerdome.com etc.)

31.Han, B., Pei, K., Huang, Y., Zhang, X., Rong, Q., Lin, Q., Guo, Y., Sun, T., Guo, C., Carnahan, D., Kempa, K.*, Uniform Self‐Forming Metallic Network as a High‐Performance Transparent Conductive Electrode. Advanced Materials 2013, 26, 873-877. 

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中国教育部科学技术二等奖 ，2023年6月（中国教育部）

“全国大学生挑战杯特等奖”（第一完成人；中国教育部；共青团中央；中国科协）

第十二届王大珩光学奖（中国光学最高奖；个人奖；中国光学学会）

第八届全国高等学校物理教学研讨会第一名（个人奖；教育部物理学类专业教学指导委员会）

2022年-至今，Nano research Energy 青年编委

2022年-至今，Materials 期刊客座主编

2023年-至今，Molecules期刊客座主编

2025年-至今，Energy Materials and Devices期刊青年编委