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仵超

bevictor伟德官网 電機系 特别研究員/助理教授、博士生導師

研究方向

高電壓外絕緣、電熱耦合嚴酷條件下的裝備絕緣、電氣設備與絕緣電介質領域的人工智能與數字化技術

高壓館308

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bevictor伟德官网電機系特别研究員,助理教授,博士生導師。入選國家級青年人才計劃(2022)。2013年7月于bevictor伟德官网電機系本科畢業;2018年7月于bevictor伟德官网電機系博士畢業。2017.3-2017.8為英國萊斯特大學訪問學者。2018.10-2022.3在美國康涅狄格大學Electrical Insulation Research Center(EIRC)從事博士後研究,2022.4-2022.11為研究助理教授(Research Assistant Professor)。2022.12入職bevictor伟德官网電機系。

主要研究方向為輸變電系統有機外絕緣;電熱耦合嚴酷條件下的裝備絕緣;電氣設備與絕緣電介質領域的人工智能與數字化技術。聚焦電熱耦合嚴酷條件下電介質分子結構對電荷輸運和弛豫過程的作用機制、電介質與電極界面有缺陷時電荷注入的可控性等科學問題,将分子工程技術與界面工程技術相結合,與合作團隊首次提出模塊化協同的電介質分子結構設計方法和抑制界面缺陷的二維塗層自組裝技術,将人工智能應用于電介質新材料研究,開發出了耐受電熱耦合嚴酷條件的電介質材料新體系。已在PNAS, Nature Communications, Adv. Mater., Energy Environ. Sci., Appl. Physic. Lett., Matter, IEEE Trans. DEI, High Volt.等期刊共發表論文90餘篇。獲國家電網公司科技進步三等獎、南方電網公司科技進步二等獎。

高電壓工程

高電壓工程(英文)

本科生探索式學習課:高電壓與絕緣新材料

2023,國家自然科學基金委,優秀青年科學基金(海外),在研,主持

2024,國家自然科學基金委,重點項目(重大研究計劃),在研,主持

2023,重點研發計劃,高降解率環氧樹脂,在研,主持子課題

2023,國網總部科技項目,高壓化儲能電池系統絕緣故障特性與防護技術,在研,主持(課題負責人)

2023,國網總部科技項目,高壓電工裝備用環氧材料性能評價及基礎數據庫框架構建,在研,主持

2024,國家電網公司共鍊行動複合絕緣子産業鍊專項,在研,負責課題一

2023,中國電科院重點實驗室開放基金,基于介電響應的高海拔複合絕緣子用矽橡膠老化狀态表征,在研,主持

2023,bevictor伟德官网,人才引進啟動經費,在研,主持

2023,電機系自主創新科研計劃項目,在研,主持

2022,國網總部科技項目,高海拔特高壓交流工程複合外絕緣設計及電暈優化研究,在研,參與

2022,DOE ARPA-e,Substation in a Cable for Adaptable, Low-cost Electrical Distribution (SCALED),參與

2019, DOD ONR,Accelerated Co-Designs of High K Polymer Dielectrics,參與

2018,DOD ONR MURI,Tracking, Diagnosing and Impeding Dielectric Breakdown in Polymers,已結題,參與

2015,國家重點研發計劃“±1100 千伏直流換流站絕緣子與外絕緣關鍵技術研究”子課題,已結題,參與

2013,973計劃項目“交直流特高壓設備外絕緣沿面放電機理及特性”子課題,已結題,參與

[1] C. Wu, A. Deshmukh, O. Yassin, Z. Li, A. Alamri, J. Vellek, P. Zhou, M. Sotzing, G. Sotzing, Y. Cao, “Flexible cyclic-olefin with enhanced dipolar relaxation for harsh condition electrification”. Proceedings of National Academy of Sciences (PNAS), US. vol. 118, no. 45, pp. e2115367118, 2021.

[2] C. Wu, A. A. Deshmukh, Z. Li, L. Chen, A. Alamri, Y. Wang, R. Ramprasad, G. A. Sotzing, Y. Cao, “Flexible temperature-invariant polymer dielectrics with large bandgap”, Advanced Materials, vol. 32, pp. 2000499, 2020.

[3] A. Deshmukh, C. Wu, O. Yassin, A. Mishra, L. Chen, A. Alamri, Z. Li, J. Zhou, Z. Mutlu, M. Sotzing, P. Rajak, S. Shukla, J. Vellek, P. Vashishta, M. Cakmak, R. Ramprasad, Y. Cao, G. Sotzing, “Flexible polyolefin dielectric by strategic design of organic modules for harsh condition electrification”. Energy & Environmental Science, DOI: 10.1039/d1ee02630e, 2022.(共同一作)

[4] B. Zhang, J. Liu, M. Ren, C. Wu, T. Moran, S. Zeng, S.E. Chavez, Z. Hou, Z. Li, A. M. LaChance, T. R. Jow, B.D. Huey, Y. Cao, L. Sun, “Reviving the Schottky barrier for flexible polymer dielectrics with a superior 2D nano-assembly coating”. Advanced Materials, vol. 33, pp. 2101374, 2021.(共同一作)

[5] C. Wu, L. Chen, A. Deshmukh, D. Kamal, Z. Li, P. Shetty, J. Zhou, H. Sahu, H. Tran, G. Sotzing, R. Ramprasad, Y. Cao, “Dielectric Polymers Tolerant to Electric Field and Temperature Extremes: Integration of Phenomenology, Informatics, and Experimental Validation”, ACS Applied Materials & Interfaces, vol. 13, pp. 53416-53424, 2021.

[6] C. Wu, A.A. Deshmukh, L. Chen, R. Ramprasad, G.A. Sotzing, Y. Cao, “Rational design of all-organic flexible high-temperature polymer dielectrics”. Matter, 5(9), pp.2615-2623, 2022.

[7]. Z. Li, C. Wu, L. Chen, Y. Wang, Z. Mutulu, H. Uehara, J. Zhou, M. Cakmak, R. Ramprasad, and Y. Cao, Probing Electronic Band Structures of Dielectric Polymers via Pre-Breakdown Conduction. Adv Mater, 2024: p. e2310497.(共同通訊)

[8]. S. Shukla, C. Wu, A. Mishra, J. Pan, A. P. Charnay, A. Khomane, A. Deshmukh, J. Zhou, M. Mukherjee, R. Gurnani, P. Rout, R. Casalini, R. Ramprasad, M. D. Fayer, P. Vashishta, Y. Cao, and G. Sotzing, Pendant Group Functionalization of Cyclic Olefin for High Temperature and High-Density Energy Storage. Adv Mater, 2024: p. e2402133.(共同一作)

[9]. R. Gurnani, S. Shukla, D. Kamal, C. Wu, J. Hao, C. Kuenneth, P. Aklujkar, A. Khomane, R. Daniels, A. A. Deshmukh, Y. Cao, G. Sotzing, and R. Ramprasad, AI-assisted discovery of high-temperature dielectrics for energy storage. Nature Communications, 2024. 15(1). (共同一作)

[10]. W. Huang, B. Wan, X. Yang, M. Cheng, Y. Zhang, Y. Li, C. Wu, Z. M. Dang, and J. W. Zha, Alicyclic Polyimide With Multiple Breakdown Self‐Healing Based on Gas‐Condensation Phase Validation for High Temperature Capacitive Energy Storage. Advanced Materials, 2024. (共同通訊)

[11]. A. A. Deshmukh, C. Wu, O. Yassin, L. Chen, S. Shukla, J. Zhou, A. R. Khomane, R. Gurnani, T. Lei, X. Liang, R. Ramprasad, Y. Cao, and G. Sotzing, Effect of Fluorine in Redesigning Energy-Storage Properties of High-Temperature Dielectric Polymers. ACS Applied Materials & Interfaces, 2023. 15(40): p. 46840-46848. (共同通訊)

[12]. 王乾, 周穎, 高岩峰, 盧毅, 鄧靖宇, 劉瑛岩, 梁曦東, 仵超, 電熱耦合條件下聚合物電介質的分子結構設計與新材料研制. 中國電機工程學報, 已接收.

[13] C. Wu, X. Liang, L. A. Dissado, N. M. Chalashkanov, S. J. Dodd, Y. Gao, S. Xu, “Dielectric Response of Nano Aluminium Tri-hydrate Filled Silicone Rubber”. Composites Science and Technology, 163, pp. 56-62, 2018.

[14] C. Wu, Z. Li, G. M. Treich, M. Tefferi, R. Casalini, R. Ramprasad, G. A. Sotzing, Y. Cao, “Dipole-relaxation dynamics in a modified polythiourea with high dielectric constant for energy storage applications”, Appl. Phys. Lett., 115, pp. 163901, 2019.

[15] Q. Wang, C. Wu, A.M. LaChance, J. Zhou, Y. Gao, Y. Zhang, L. Sun, Y. Cao, X. Liang, “Interfacial polarization suppression of P (VDF-HFP) film through 2D montmorillonite nanosheets coating”. Progress in Organic Coatings, 172, p.107119, 2022.

[16] C. Wu, A.M. LaChance, M.A. Baferani, K. Shen, Z. Li, Z. Hou, N. Wang, Y. Wang, L. Sun, Y. Cao, “Scalable self-assembly interfacial engineering for high-temperature dielectric energy storage”. iScience, 25(7), p.104601, 2022.

[17] Q. Wang, W. Bao, Y. Gao, S. Liu, Z. Zuo, C. Wu, X. Liang, “Influence of Surface Discharge on Resin Degradation in Decay-like Fracture of Composite Insulators”. Polymers, vol. 15, no. 4, p. 790, 2023.

[18] C. Wu, L.A. Dissado, Y. Gao, Q. Wang, Y. Liu, Y. Cao, X. Liang, “Dielectric response—A nondestructive approach to probing the micro‐interface of aluminium hydroxide filled silicone rubber composites for outdoor insulation”. High Voltage, 2023.

[19] C. Wu, A. A. Deshmukh, Z. Li, L. Chen, A. Alamri, Y. Wang, R. Ramprasad, G. A. Sotzing, Y. Cao, “Remarks on the Design of Flexible High-Temperature Polymer Dielectrics for Emerging Grand Electrification - Exemplified by Poly(oxa)norbornenes”. IEEE Trans. Dielectr. Electr. Insul., vol. 28, pp. 1468-1470, 2021.

[20] C. Wu, M. A. Baferani, J. Ronzello, Y. Cao, “Charge Transport Dynamics and Space Charge Accumulation in XLPE Composites with 2D Platelet Fillers for HVDC Cable Insulation”. IEEE Trans. Dielectr. Electr. Insul., vol. 28, pp. 3-10, 2021.

[21] C. Wu, X. Liang, S. Xu, S. Li, Y. Gao, Y. Liu, “Effect of Alumina Tri-hydrate Surface Modification on Liquid Permeation and Electrical Performance of Silicone Rubber”. IEEE Trans. Dielectr. Electr. Insul., 24(1): 543-551, 2017.

[22] C. Wu, Y. Gao, X. Liang, S. M. Gubanski, Q. Wang, W. Bao, S. Li, “Manifestation of Interactions of Nano-Silica in Silicone Rubber Investigated by Low-Frequency Dielectric Spectroscopy and Mechanical Tests”, Polymers, 11, pp.717, 2019.

[23] Q. Wang, X. Liang, C. Wu, N. Wang, S. Liu, Z. Zuo, Y. Gao, “Temperature Dependence and Correlation of Polarization Processes in P(VDF-HFP) Films”, Polymer, 229, 124016, 2021.

[24] Alamri, C. Wu, A. Mishra, L. Chen, Z. Li, A. Deshmukh, J. Zhou, O. Yassin, R. Ramprasad, P. Vashishta, Y. Cao & G. Sotzing. “Improving the Rotational Freedom of Polyetherimide: Enhancement of the Dielectric Properties of a Commodity High-Temperature Polymer Using a Structural Defect”. Chemistry of Materials, 34(14), pp.6553-6558, 2022.

[25] Alamri, C. Wu, S. Nasreen, Y. Cao, G. Sotzing, “High Dielectric Constant and High Breakdown Strength Polyimide via Tin Complexation of the Polyamide Acid Precursor”. RSC Advances, DOI: 10.1039/d1ra06302b, 2022.

[26] S. M. Fica-Contreras, Z. Li, A. Alamri, A. P. Charnay, J. Pan, C. Wu, J. R. Lockwood, O. Yassin, S. Shukla, G. Sotzing, Y. Cao, M. D. Fayer, “Synthetically tunable polymers, free volume element size distributions, and dielectric breakdown field strengths”. Materials Today, 2023.

  • 中國電機工程學會會員

  • IEEE PES中國區高壓絕緣技術委員會理事

  • IEEE會員

  • CIGRE D1中國工作組成員、秘書

  • CIGRE會員

  • 複合材料學會介電專委會委員

  • CIGRE JWG C4A3B2B4.75工作組成員

  • 中國物理學會靜電專委會委員

  • 中國電工技術學會會員

  • 複合材料學會電網工程材料專委會委員

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