论文成果【动态更新】
2026年
[1] Ren S, Zhou W*, Zheng Y*, et al. Research on Power Frequency Insulation Properties and Configurations of CF3SO2F Gas Mixture for Industrial Applications[J]. High Voltage, 2026. (early access, 共同通讯)
[2] Wang A, Li Z, Ren S, et al. Probing the thermal decomposition mechanism of CF3SO2F by deep learning molecular dynamics[J]. Communications Chemistry, 2026, 9(1): 40. (共同通讯)
[3] 郑宇*,郝东昕,刘伟,任书波,颜湘莲,高克利,周文俊. CF3SO2F三元混合气体的工频击穿特性研究[J].中国电机工程学报,2026, 46(1): 424-434.(一作+通讯)
[4] 赵思洋,何文敏,刘兵,石龙,叶尔深·艾尔肯,郑宇*.发电机出口侧电压互感器匝间短路故障诊断研究[J/OL].绝缘材料,1-10. (early access,通讯)
[5] 赵思洋,何文敏,刘兵,石龙,叶尔深·艾尔肯,郑宇*.发电机出口电压互感器匝间短路电流特性及其在线监测研究[J/OL]. 电瓷避雷器, 1-9. (early access,通讯)
2025年
[1] Y. Zheng, D. Hao, W. Liu, S. Ren and W. Zhou. Ionization and Attachment Properties of Gas Mixtures With CF₃SO₂F Plus Air/CO₂/N₂[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2025, 32(5): 2748-2755. (一作+通讯)
[2] Han Ro, Xuhao, Yu Wei, Su Jinhao, Ke Xue, Zheng Yu, Zhou Wenjun, Zhang Zhaofu*, Guo, Yuzheng*. Gas Sensing of C3F7CN Decomposition Products on Doped h-AlN Monolayer: A DFT-NEGF Study[J]. IEEE SENSORS JOURNAL, 2025, 25(1): 135-143. (共同通讯)
[3] Peng C, Dong X, Sabariego R V, et al. A Full 3-D Model for Positive Long Air-Gap Discharge Simulation[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2025, 32(6): 3199-3208.
[4] Yang H, Li H, Jin C, et al. Feasibility Study of Using C4F7N/Helium in Eco-Friendly Gas-Insulated Transformer: Dielectric Strength and Heat Dissipation Performance[J]. IEEE Transactions on Power Delivery, 2025, 40(5): 2811-2819.
[5] X. Xu, C. Zhang, Y. Luo, W. Liu, W. Wu, Y. Zheng, T. Shao. Discharge Characteristics of CF3SO2F/N2 Gas Mixture in Non-Uniform Fields Under Power Frequency AC Voltage[J]. IEEE Transactions on Dielectrics and Electrical Insulation, doi: 10.1109/TDEI.2025.3620781. (early access)
[6] 向志辉,郑宇*,任书波,等. 六氟-2-丁炔及其与N2混合的电离与击穿特性[J]. 中国电机工程学报, 2025, 45(10): 4067-4077. (通讯)
[7] 王锦聪,李毅恒,郑宇,高克利,裴学凯*. 基于丁达尔效应的新型环保绝缘气体稳定性评估 [J]. 高电压技术, 2025, 51 (06): 2672-2679.
[8] 陈兴发,郑宇*,任书波,等. CF3SO2F气体与Al(111)表面相容性及其分解特性模拟 [J]. 绝缘材料, 2025, 58 (02): 66-75. (通讯)
[9] 程西,梁亚峰,马立红,郑宇*,董旭柱. 基于充放电损耗特性的独立微电网储能设备状态量研究 [J]. 电气工程学报, 2025, 20 (2): 362-370.
[10] 邱睿,周文俊,高克利,郑宇,王宝山,罗运柏,涂彦昕,顾建伟. SF6绝缘设备环保气体阶段性替代策略[J/OL].中国电机工程学报,1-13[2025-11-11].https://doi.org/10.13334/j.0258-8013.pcsee.250747.
[11] 高克利,郑宇,颜湘莲,王宝山,董利,王雯,刘伟,李俊峰. 新型环保绝缘气体三氟甲基磺酰氟(CF3SO2F)研究进展[J].高电压技术,2025,51(8):4060-4075.
[12] 杨帆,韩睿,蒋鹏,王文浩,郑宇*,董旭柱. 基于状态量优化的氧化锌避雷器健康状态评估研究[J/OL].电瓷避雷器,1-10[2025-11-11].https://link.cnki.net/urlid/61.1129.TM.20250422.1740.010.(通讯)2024年
[1] R. Han, . Theoretical study of the compatibility between environmentally friendly insulation gas CF3SO2F and silver, zinc, and zinc oxide materials in gas-insulated equipment[J]. Journal of Physics D: Applied Physics, vol. 57, no. 38, Sep. 2024, doi: 10.1088/1361-6463/ad58ef.
[2] W.
[3] W. Liu, Y. Zheng, W. Zhang, F. Ma, Z. Tao, Y. Guo and W. Zhou. Experimental Study of Compatibility between the Eco-friendly Insulation Mixed Gas CF3SO2F/N2 and EPDM and CR Materials[J], ACS Omega, pp. 7958–7966, Sep. 2024, doi: 10.1021/acsomega.3c07958.
[4] R. Qiu, W. Zhou, P. Brault, Y. Zheng, G. Li, H. Yang and H. Li. A Method to Localize the Axial Position of Partial Discharges in GIL by Gas Sensors[J], IEEE Transactions on Dielectrics and Electrical Insulation, 2024, 31(1), 263-270. doi: 10.1109/TDEI.2023.3320094.
[5] J. Wang, C. Man, Y. Li, Y. Luo, Y. Zheng, Q. Xiong, X. Pei. Adsorption of CF3SO2F decomposition products by HfS2 vacancy structures as a promising detection device: A DFT study[J]. SURFACES AND INTERFACES, 2024, 45, 103868. doi: 10.1016/j.surfin.2024.103868.
[6] 苑伟光, 高克利, 任书波, 郑宇,章程. CF3SO2F/N2混合气体中柱式环氧树脂绝缘子沿面闪络特性[J].高电压技术, 2024, 50(12): 5388-5396. DOI:10.13336/j.1003-6520.hve.20231889.
[7] 陶子林, 赵思洋, 郑宇, 任书波,郝东昕,向志辉,周文俊. O2体积分数对N2/O2混合气体工频绝缘强度的影响[J].高压电器,2024,60(9):40-45.DOI:10.13296/j.1001-1609.hva.2024.09.006.
[8] 陈远东, 郑宇, 孟辉, 沈腾达,梁建,周文俊. 温度对SF6/CF4混合气体尖板放电特性的影响[J].高压电器,2024,60(9):61-68.DOI:10.13296/j.1001-1609.hva.2024.09.009.
[9] 陈远东, 郑宇. SF6混合气体放电的极性反转特性研究[J].高压电器,2024,60(7):114-121.DOI:10.13296/j.1001-1609.hva.2024.07.012.
[10] 马秉伟, 陈晓国, 郑宇, 刘凯,陶子林,彭瑞超,王宝山,袁佳歆. 电力变压器环保绝缘油研究进展与趋势[J].南方电网技术,2024,18(5):12-21+30. DOI:10.13648/j.cnki.issn1674-0629.2024.05.002.
[11] 向志辉, 郑宇, 任书波, 周文俊,朱太云. CF3SO2F/N2混合气体的电离特性试验研究[J].高电压技术,2024,50(3):1331-1339.DOI:10.13336/j.1003-6520.hve.20230271.
[12] 陶子林, 郑宇, 高克利, 朱太云,刘伟,周文俊. 低温下C4F7N/CO2混合气体的绝缘特性与参数配置[J].高电压技术,2024,50(2):832-841.DOI:10.13336/j.1003-6520.hve.20221703.2023年
[1] Han R, Zhang Z, Liu W, et al. Theoretical insights into the two-dimensional gallium oxide monolayer for adsorption and gas sensing of C4F7N decomposition products[J]. Journal of Materials Chemistry C, 2023, 11(35): 11928-11935.(共同通讯)
[2] Qiu R, Zhou W*, Zheng Y*, et al. Prediction models of the ionization coefficient and ionization cross-section based on multi-layer molecular parameters[J]. Plasma Science and Technology, 2023, 25(5): 055405.(共同通讯)
[3] Wan X, Zhang Z, Wang A, et al. Deep-learning-assisted theoretical insights into the compatibility of environment friendly insulation medium with metal surface of power equipment[J]. Journal of Colloid and Interface Science, 2023, 648: 317-326.(共同通讯)
[4] 任书波,周文俊,郑宇,等. HFO-1336mzz(E)/X混合气体工频绝缘特性试验研究[J].高电压技术,2023,49(11):4527-4534.
[5] 郑宇,陶子林,周文俊*,等. 欧盟含氟气体法规对C4F7N气体应用的影响[J].高电压技术,2023,49(11):4471-4479. (一作)
[6] 陶子林,郑宇*,周文俊,等. 微水条件下SF6/CF4混合气体中的低温沿面放电特性[J].高压电器,2023,59(09):27-34. (通讯)
[7] 周文俊,邱睿,高克利,等. 环保气体绝缘强度预测模型研究现状[J].高电压技术,2023,49(03):895-906.
[8] 吕浥尘,郑宇*,朱太云,等. 五种吸附剂与C4F7N气体及CF3SO2F气体的相容性试验研究[J].电工技术学报,2023,38(S1):196-203. (通讯)
[9] 周文俊,邱睿,郑宇*,等. 环保绝缘气体介电强度预测方法评估[J].电工技术学报,2023,38(S1):214-221. (通讯)
[10] 彭长志,董旭柱,赵彦普,等. 正极性先导起始与发展过程中的等离子体特征[J].电工技术学报,2023,38(02):533-541.
[11] 韩蓉,郭宇铮,高克利,等. β-Ga2O3(010)表面对新型环保绝缘气体CF3SO2F的气敏响应特性[J].高电压技术,2023,49(03):990-999.
[12] 万旭昊,郭宇铮,高克利,等. 基于第一性原理的新型环保绝缘介质CF3SO2F相容性评估[J].高电压技术,2023,49(07):2848-2857.
[13] 郑宇,周文俊*,朱太云,等. 基于汤逊放电的C4F7N/CO2摩尔分数检测[J].高电压技术,2023,49(03):946-954. (一作)