一、个人基本信息

出生年月：1990年1月

籍贯：山东

性别：男

民族：汉

职称：副教授

政治面貌：中共党员

最高学历：博士研究生

工作单位：中国民航大学理学院

通讯地址：天津市东丽区津北公路2898号

邮政编码：300300

办公电话：可忽略

电子邮箱：mingchaowang0@163.com

二、学习和工作经历

学习经历：

2015/09 – 2016/11，康涅狄格大学（美），化学系，联合培养；

2011/09 – 2017/01，天津大学，材料科学与工程学院材料学专业，博士（硕博连读）；

2007/09 – 2011/06，济南大学，材料科学与工程学院材料科学与工程专业，学士；

工作经历：

2020/12-至今，中国民航大学，理学院，副教授；

2017/12 – 2020/12，中国民航大学，理学院，讲师；

三、招生专业

材料科学与工程、物理学

四、主讲课程

无损检测、普通物理、物理实验

五、主要研究方向

高温热防护材料、耐高温胶黏剂、阻燃隔热涂层等

六、主持和参与的项目

[1] 锂电池热失控防护用晶须原位生长消氟-抗烧蚀阻燃隔热涂层的制备与性能研究, 民航热灾害防控与应急重点实验室开放基金课题，2024.12-2026.11，主持；

[2] ×××胶的改性设计与热处理反应机制研究，中国工程物理研究院化工材料研究所，横向课题，2024/08至2025/12，主持；

[3] 基于热膨胀性能调控的锆掺杂改性磷酸铝基耐高温胶的制备与粘结机理研究，中央高校基本科研业务费重点项目，2024/01至2026/12，主持；

[4] 陶瓷/高温合金用高性能叠层梯度耐高温胶的制备与胶接维修机理研究，天津市应用基础研究多元投入项目，2023/11至2025/10，主持；

[5] 钛合金/陶瓷纤维布柔性传感网络搭建用耐高温胶的制备与性能研究，智能制造装备与技术全国重点实验室开放课题，2023/01至2024/12，主持；

[6] 无机晶须低温原位生长自增韧耐高温胶黏剂的制备与增韧机制研究，国家自然基金青年项目，2019/01至2021/12，主持；

七、学术兼职

Ø MDPI-Materials期刊特邀编辑；

Ø Materials Technology Reports期刊编辑；

Ø 天津市企业科技特派员；

Ø Journal of Advanced Ceramics期刊青年博士审稿团；

Ø Chemical Engineering Journal、Ceramics International、Journal of Materials Science、International Journal of Adhesion and Adhesives等期刊审稿人；

八、一作与通讯论文

[1] G. Cai, A. Liu, Y. He, Z. Hu, J. Bian, Y. Zhang, H. Zhang, M. Wang*, Preparation and performance analysis of a novel zirconium-doped silicone resin modified epoxy resin-based intumescent flame-retardant and thermal-insulating coating, Chemical Engineering Journal, 2025, 520, 165996. https://doi.org/10.1016/j.cej.2025.165996.

[2] J. Liu, X. Ji, M. Wang*,Preparation and properties of ZrB₂-modified aluminum/zirconium phosphate-based high-temperature-resistant adhesives for joining zirconia ceramics, Ceramics International, 2025, doi.org/10.1016/j.ceramint.2025.04.105.

[3] A.L Liu, Z. Gao, G.S. Cai, M.C. Wang*, Preparation and characterization of expandable graphite/silicone resin co-modified polyurethane-based intumescent flame retardant thermal insulation coatings, Progress in Organic Coatings, 205 (2025) 109316.

[4] C. Qi, X. Ji, J. Li, Z. Hu, X. Wei, B. Xiao, M. Wang*, The preparation and performance analysis of high- entropy phosphate high-temperature resistant adhesives, Journal of the European Ceramic Society, 45 (2025) 117356.

[5] R. Zhang, J. Li, Z. Wang, C. Qi, J. Zhuo, Y. Wan, Y. Zhang, H. Liu , B. Xiao, M. Wang*, Preparation of porous mullite ceramics composed entirely of overlapping and interlocking mullite whiskers through whisker in-situ growth. Journal of Advanced Ceramics, 2025, 9221055. https://doi.org/10.26599/JAC.2025.9221055

[6] G. Cai, A. Liu, D. Jiang, Z. Hu, J. Li, Y. Wan, Z. Gao, Y. Zou, X. Zhou, H. Zhang, M. Wang*, Preparation and performance analysis of organic polyborosilazane-modified epoxy resin-based intumescent flame-retardant thermal insulation coatings, Progress in Organic Coatings, 199 (2025) 108952.

[7] J. Li, J. Liu, Y. Zhang, Y. Wan, J. Liu, G. Cai, X. Tao, W. Jing, M. Wang*, Preparation and properties of high-temperature resistant inorganic phosphate-based adhesive for connecting quartz glass at elevated temperatures, Ceramics International, 2024, 50, 45986-46001.

[8] J. Liu, Y. Wan, B. Xiao, J. Li, Z. Hu, R. Zhang, H. Liu, M. Wang*, The preparation and performance analysis of zirconium-modified aluminum phosphate-based high-temperature (RT-1500°C) resistant adhesive for joining alumina in extreme environment. Journal of Advanced Ceramics, 2024, 13(7): 911-932.

[9] N. Yang, R. Zhang, T. Qin, Y. Zhang, X. Wei, Z. Wang, Z. Feng, M. Wang, The effect of multiple factors on the synthesis of mullite whiskers based on the S-L-S mechanism and the comparison of strengthening performance. Journal of Alloys and Compounds 997 (2024) 174947.

[10] N. Yang, G. Cai, Y. Wan, R. Zhang, H. Zhang, M. Wang*, High anti-ablative epoxy resin-based flame retardant and thermal insulation coating based on spontaneous ceramization and vitrification. Ceramics International, 2024, https://doi.org/10.1016/j.ceramint.2024.04.154

[11] M. Wang*, Z. Zhou, Z. Liang, S. Du, G. Cai, X. Wang, Y. Zhou, H. Zhang. The preparation and fire extinguishing mechanism research of a novel high-efficiency KHCO₃@HM dry powder. Materials Today Communications, 38, 2024. 107817.

[12] X. Yang, Y. Wan, N. Yang, Y. Hou, D. Chen, J. Liu, G. Cai, M. Wang*, The effect of different diluents and curing agents on the performance of epoxy resin-based intumescent flame-retardant coatings. Materials, 2024, 17(2), 348.

[13] X. Tao, J. Li, J. Liu, G. Cai, J. Zhang, M. Wang*. Improved oxidation resistance and infrared emissivity of tantalum disilicide particles with sol-gel derived SiO₂ coatings. Journal of Alloys and Compounds, 971 (2024) 172765.

[14] G. Cai, Y. Wan, J. Liu, N. Yang, J. Guo, J. Li, Y. Zhou, J. Zhang, H. Zhang, M. Wang*. Preparation and performance analysis of methyl silicone resin-modified epoxy resin-based intumescent flame retardant thermal insulation coating. Journal of Micromechanics and Molecular Physics, 8 (2023) 61-82.

[15] X. Dong, Q. An, S. Zhang, H. Yu, M. Wang*. Porous ceramics based on high-thermal-stability Al₂O₃-ZrO₂ nanofibers for thermal insulation and sound absorption applications. Ceramics International, 49 (2023) 31035-31045.

[16] G. Cai, J. Wu, J. Guo, Y. Wan, Q. Zhou, P. Zhang, X. Yu, M. Wang*. A Novel Inorganic Aluminum Phosphate-Based Flame Retardant and Thermal Insulation Coating and Performance Analysis. Materials, 16 (2023) 4498.

[17] Z. Liang, J. Liu, Y. Wan, Z. Feng, P. Zhang, M. Wang*, Haijun Zhang. Preparation and fire extinguishing mechanism of novel fire extinguishing powder based on recyclable struvite. Materials Today Communications, 34 (2023) 105410.

[18] Z. Liang, Z. Zhou, Y. Sun, Y. Huang, X. Guo, G. Cai, M.C. Wang*, et al., Fire extinguishing performance of chemically bonded struvite ceramic powder with high heat-absorbing and flame retardant properties, Materials, 2022, 15, 8021.

[19] M.C. Wang, Z.L. Liang, S.Q. Yan, X. Tao, Y.L. Zou, et al., The preparation and property analysis of B₄C modified inorganic amorphous aluminum phosphates-based intumescent flame retardant coating, Construction and Building Materials, 2022, 359 (2022) 129480.

[20] X. Tao, Z.L. Liang, J.C. Li, J.F. Zhang, X.Y. Guo, M.C. Wang*, Anti-oxidation of emissing agents in TaSi₂-MoSi₂-borosilicate glass high emissivity coating, Ceramics International, 2022, 48, 37333-37343 Doi: 10.1016/j.ceramint.2022.08.310.

[21] Z.L. Chen, J.X. Liu, Y. Wu, Z.J. Feng, J.C. Li, Z.Y. Feng, Q.S. Zhang, M.C. Wang*, The preparation and properties of an alloying modified ceramic-precursor high-temperature resistant adhesive for joining zirconia ceramics and titanium-based superalloys, Materials Today Communications, 33 (2022) 104353.

[22] H.Z Zhang, K. Li, Z.L. Liang, Y. Wan, Z.Y. Feng, J.C. Liu, Q.S. Zhang, M.C. Wang*, Replacement of interlayer anion via memory effect of layered double hydroxide: A promising strategy for fabricating nanostructures with better flame-retardant performance, Journal of Physics and Chemistry of Solids, 170 (2022) 110932.

[23] J.F. Zhang, Z.L. Liang, J.X. Liu, Y.G. Wan, X. Tao, H.J. Zhang, M.C. Wang*, Preparation and performance analysis of palygorskite reinforced silicone-acrylic emulsion-based intumescent coating, Progress in Organic Coatings, 166 (2022) 106801.

[24] C.X. Zhai, Y. Zhong, J.X. Liu, J. Zhang, Y.M. Zhu, M.C. Wang*, J.J. Yeo, Customizing the properties of borosilicate foam glasses via additions under low sintering temperatures with insights from molecular dynamics simulations, Journal of Non-Crystalline Solids, 576 (2022) 121273.

[25] M.C. Wang, J.X. Liu, Z.L. Chen, X.X. Hu, W.Z. Zhai, et al., Joining zirconia with nickel-based superalloys for extreme applications by using a pressure-free high-temperature resistant adhesive, Ceramics International, 48 (2022) 8025-8030.

[26] M.C. Wang, Z.L. Chen, J.X. Liu, Z.J. Feng, J.F. Zhang, et al., Advanced high-temperature (RT-1100°C) resistant adhesion technique for joining dissimilar ZrO₂ ceramic and TC4 superalloys based on an inorganic/organic hybrid adhesive, Ceramics International,48 (2022) 3081-3095.

[27] M.C. Wang, K. Li, R.Y. Lu, Z.J. Feng, T. Wei, et al., Advanced high-temperature resistant (RT-1000°C) aluminum phosphate-based adhesive for titanium superalloys in extreme environments, Ceramics International, 47 (2021) 32988-33001.

[28] M. Wang, F. Bu, C. Zhou, Q. Zhou, T. Wei, J. Liu and W. Zhai, Bonding performance and mechanism of a heat-resistant composite precursor adhesive (RT-1000℃) for TC4 titanium alloy, J. Micromech. Mol. Phys., 5 (2020) 2050016.

[29] M.C. Wang*, C. Zeng, Y. Guo, T. Wei, Z. Feng, J. Zhang, J. Liu, H. Zhang, In situ growth of SiC nanowires toughened preceramic resin-based adhesive for connecting Cf/C composites in extreme environments, Ceramics International, 46 (2020) 24860-24872.

[30] M.C. Wang, Z. Feng, C. X. Zhai*, Q.J. Zhou, Chromiun carbide micro-whiskers: preparation and strengthening effects in extreme conditions with experiments and molecular dynamics simulations, Journal of Solid State Chemistry, 291 (2020) 121598.

[31] M.C. Wang*, J. Zhang, T. Wei, Q.J. Zhou, Z.P. Li, Effect of Al:P ratio on bonding performance of high-temperature resistant aluminum phosphate adhesive, International Journal of Adhesion and Adhesives, 100 (2020) 102627.

[32] M.C. Wang, F.J. Feng, C.X. Zhai, Z.F. Zhang, Z.P. Li, et al., Low-temperature in-situ grown mullite whiskers toughened heat-resistant inorganic adhesive, Journal of Alloys and Compounds, 836 (2020) 155349.

[33] F.J. Feng, M.C. Wang*, R.Y. Lu, W.C. Xu, T. Zhang, et al., A composite structural high-temperature-resistant adhesive based on in-situ grown mullite whiskers, Materials Today Communications, 23 (2020) 100944.

[34] H.J. Zhang, C.C. Xu, K. Li, Y.R. Ding, M.C. Wang*, et al., Be₃BN₃ monolayer with ultrawide band gap and promising stability for deep ultraviolet applications, Computational Materials Science, 177 (2020) 109552.

[35] X. Dong, M.C. Wang*, Xin Tao, J.C. Liu, A.R. Guo, et al., Properties of heat resistant hollow glass microsphere phosphate buoyancy materials with different coatings, Ceramics International, 46 (2020) 415-420.

[36] M.C. Wang, X. Dong, Q.J. Zhou, Z.J. Feng, Y.L. Liao, et al., An engineering ceramic-used high-temperature-resistant inorganic phosphate-based adhesive self-reinforced by in-situ growth of mullite whiskers, Journal of the European Ceramic Society, 39 (2019) 1703-1706.

[37] M.C. Wang, L.Y. Li, Z.Y. Li, M.R. Du, J.C. Liu, et al., Mullite whiskers grown in situ reinforce a pre-ceramic resin adhesive for silicon carbide ceramics, Ceramics International, 45 (2019) 11131-11135.

[38] M.C. Wang, Z.P. Li, R.Y. Lu, J.C. Liu, A.R. Guo, et al., The connection and repair of Ni-based superalloys by a simple heat-resistant adhesion technique, Journal of Alloys and Compounds, 791 (2019) 1146-1151.

[39] M.C. Wang, Q.G. Song, Y.Q. Gu, C.R. Wu, J.C. Liu, et al., Multiple high-temperature resistant phases modified phosphate-based adhesive for engineering ceramic connection in extreme environment, Ceramics International, 45 (2019) 516-521.

[40] S.T. Xie, M.C. Wang*, Z. Gong, R.L. Liu, X.X. Wang et al., A novel heat-resistant resin-based adhesive for high-temperature alloy connection and repair, Journal of Alloys and Compounds, 774 (2019) 46-51.

[41] X.Q. Zhang, M.C. Wang*, T. Jia, X.H. Ma, Q.J. Song, et al., A heat-resistant glass-modified multi-component phosphate adhesive for repair and connection of superalloy in extreme environment, Journal of Alloys and Compounds, 745 (2018) 868-873.

[42] J.K. He, M.C. Wang^₸(共同一作), W.B. Wang, et al. Hierarchical Mesoporous NiO/MnO₂@PANI Core-Shell Microspheres Highly Efficient and Stable Bifunctional Electrocatalysts for Oxygen Evolution and Reduction Reactions, ACS Appl Mater Interfaces. 9 (2017 ) 42676-42687.

[43] M.C. Wang, X. Tao, X. Q. Xu, et al. High-temperature bonding performance of modified heat-resistant adhesive for ceramic connection. Journal of Alloys and Compounds, 663 (2016) 82-85.

[44] M.C. Wang, R. Miao, J. He, et al. Silicon Carbide whiskers reinforced polymer-based adhesive for joining C/C composites. Materials and Design, 99 (2016) 293-302.

[45] M.C. Wang, J.C. Liu, A.R. Guo, et al., Preparation and Performance of the Room-Temperature-Cured Heat-Resistant Phosphate Adhesive for C/C Composites Bonding. International Journal of Applied Ceramic Technology, 12 (2015) 837-845.

[46] M.C. Wang, J.C. Liu, H.Y. Du, et al., A SiC whisker reinforced high-temperature resistant phosphate adhesive for bonding carbon/carbon composites. Journal of Alloys and Compounds, 633 (2015) 145-152.

[47] M.C. Wang, X. Dong, X. Tao, et al., Joining of various engineering ceramics and composites by a modified preceramic polymer for high-temperature application. Journal of the European Ceramic Society, 35 (2015) 4083-4097.

[48] M.C. Wang, X. Hu, X. Xu, et al., A user-friendly heat-resistant modified polymer-based adhesive for joining and repair of carbon/carbon composites. Materials and Design, 86 (2015) 709-713.

[49] M.C. Wang, M. Zhuang, X. Tao, et al., High temperature bonding effect of the room-temperature-curing phosphate adhesive for C/C composites. Key Engineering Materials, 680 (2015) 179-183.  

[50] M.C. Wang, J.C. Liu, H.Y. Du, et al., Joining of C/C composites by using B₄C reinforced phosphate adhesive. Ceramics International, 40 (2014) 11581-11591.

[51] M.C. Wang, J.C. Liu, H.Y. Du, et al., Joining of silicon carbide by a heat-resistant phosphate adhesive. RSC Advances, 4 (2014) 31821-31828.

[52] M.C. Wang, J.C. Liu, H.Y. Du, et al., A new practical inorganic phosphate adhesive applied under both air and argon atmosphere. Journal of Alloys and Compounds, 617 (2014) 219-221.

九、授权发明专利

[1] 王明超, 冯振宇, 张海军, 刘靖炫, 孙芸琪, 周青军．氧化锆陶瓷专用硅硼碳锆改性磷酸铝锆高温胶的制备方法, 2024-3-19, 中国, 202310464500X．(已转让)

[2] 张海军, 梁子龙, 王明超, 周志吉．一种改性鸟粪石超细干粉的制备方法．2023-8-8, 中国, ZL202210882495.X．

[3] 王明超, 张青松, 张海军, 蔡国帅, 郭欣娅．一种遇火高度陶瓷化的磷酸盐胶基阻燃隔热涂料制备方法, 2023-6-27, 中国, 202211275204.7．

[4] 王明超, 张青松, 冯振宇, 吴煜, 陈兆立．一种片状蓝晶石原位生长锁合自强化型磷酸盐基高温胶制备方法, 2023-4-28, 中国, ZL 202210816108.2．

[5] 王明超, 吴煜, 朱应国, 伍嘉萱．一种遇火自玻璃化抗烧蚀的水基阻燃隔热涂料的制备方法, 2023-5-12, 中国, ZL 202210926625.5．

[6] 王明超, 张海军, 张青松, 罗星娜, 刘靖炫．一种专用于氧化锆陶瓷与钛基合金的高温胶黏剂制备方法, 2023-1-24, 中国, ZL202111112862.X．

[7] 王明超, 张海军, 周青军, 罗星娜．碳化硅纳米线原位生长增韧陶瓷前驱体型高温胶制备方法, 2022-2-4, 中国, ZL202010555018.3．(已转让)

[8] 王明超, 冯钊杰, 罗星娜, 卢若云．一种莫来石晶须低温生长增韧型磷酸铝基高温胶制备方法, 2021-12-10, 中国, ZL201910891443.7．

[9] 王明超, 周晓猛, 罗星娜, 廖云龙．莫来石晶须原位生长自增韧型磷酸铝基耐高温胶制备方法, 2021-5-18, 中国, ZL201811373108.X．

[10] 王明超, 卢若云, 罗星娜, 冯钊杰．一种适用于TC4钛基合金的高温胶黏剂制备方法, 2021-9-24, 中国, ZL201910891291.0．

[11] 周晓猛, 王明超, 罗星娜, 李秀涛．一种适用于镍基合金的高温胶黏剂制备方法, 2021-1-1, 中国, ZL201810767356.6．(已许可)

[12] 王明超, 罗星娜, 冯钊杰, 刘正宏．一种磷酸铝胶基无卤高膨胀型阻燃隔热防火涂料制备方法, 2021-7-6, 中国, ZL201911037561.8．（已作价入股）

[13] 李秀涛, 罗星娜, 王明超, 周晓猛．一种高比表面积氟/氯交换催化剂的制备方法, 2020-12-01, 中国, ZL201810620215.1．

[14] 王明超, 郭然, 罗星娜, 周青军．一种液体表面张力系数自动测量仪, 2021-1-1, 中国, ZL202021135990.7．(已转让)

[15] Haijun Zhang, Mingchao Wang, Qingsong Zhang, Zhenyu Feng, Yu Wu, Preparation method of phosphate-based high-temperature-resistant adhesive self-reinforced by in-situ growth and locking of flaky kyanite, US Patent, US11866612B1, 2023.9.27.

[16] Qingsong Zhang, Mingchao Wang, Haijun Zhang, Preparation method of heat-resistant adhesive of silicon-boron-carbon-zirconium modified aluminum-zirconium phosphate for zirconium oxide ceramics, US Patent, US18/430662, 2024.4.30.