刘超，教授，博士生导师，国家优秀青年科学基金获得者。长期立足于国家重大战略中材料腐蚀防护实际需求，开展材料微区腐蚀电化学技术前沿理论与应用、腐蚀大数据理论与技术和人工智能（AI+）耐蚀新材料开发等研究工作。2016年和2020年分别在比利时布鲁塞尔自由大学（Vrije Universiteit Brussel）和美国麻省理工学院（Massachu-setts Institute of Technology）访学。主持国家自然科学基金优秀青年科学基金项目、面上基金项目、青年基金项目、科技部高端外国专家引进计划项目、博士后基金和中央高校基本科研项目10余项，校企合作项目30余项，作为项目骨干参加国家重点研发计划、国家自然科学基金重点基金等项目5项。在Corrosion Science和Journal of Materials Science & Technology等高水平期刊发表SCI论文100余篇、H因子30、I10因子56，主编英文专著2部、授权发明专利16项，转化4项，参编、参修团体标准57项。先后被邀在欧洲腐蚀大会、世界腐蚀大会、全国腐蚀大会等国内外学术会议做报告20余次。担任中国腐蚀与防护学会耐蚀钢专业委员会副秘书长、国家材料腐蚀与防护科学数据中心管理部副部长、中关村材料技术联盟金属材料腐蚀与防护领域委员会副秘书长，兼任《Journal of Iron and Steel Research , International》、《Metals》、《Corrosion Communications》、《中国腐蚀与防护学报》等期刊编委/青年编委。先后获北京市科学技术发明一等奖（2020）、中国腐蚀与防护学会科学技术一等奖（2021、2022）、湖北省科学技术二等奖（2022）、河北省科学技术进步二等奖（2024、2025）等省部级奖励近10项，获中国腐蚀与防护学会“杰出青年”成就奖（2023）、国际腐蚀理事会青年科学家奖（2024）。
多年来团队坚持“上天入地”的研究，在攻关前沿科学问题及理论的同时，开展成果的工程转化应用，立足国家重大战略，服务国家经济建设。近年来多项科研成果在川藏线大渡河特大桥、深中通道-狮子洋跨海大桥、国家电网、新疆罗若高速铁路等国家重大工程及装备用得到直接应用，相关技术应用受到多家用户单位的高度评价。
培养学生多人获得全国大学生冶金科技竞赛一等奖、国家奖学金、北京科技大学校长奖章、北京科技大学校十佳学术之星、北京市三好研究生、院长奖章、企业奖学金、校优秀三好研究生等荣誉。多名学生被推荐前往国内外顶尖学术机构深造，或进入高校和国家电网、北汽研究院、国电投、铁科院等大型国有企业工作。

1. 材料自然环境腐蚀规律机理与先进腐蚀评价技术
2. 微区腐蚀电化学理论与腐蚀大数据理论技术
3. 人工智能（AI+）耐蚀新材料开发
4. 特种环境材料耐蚀适用性研究与调控机理

部分获奖信息：

2020年，北京市科学技术发明一等奖；

2025年，河北省科学技术进步二等奖；

2025年，中国腐蚀与防护学会科学技术一等奖；

2024年，国际腐蚀理事会青年科学家奖；

2024年，河北省科学技术进步二等奖；

2024年，中国钢结构协会科学技术进步一等奖；

2023年，中国腐蚀与防护学会“杰出青年”成就奖；

2023年，永钢优秀教师奖

2022年，湖北省科学技术二等奖；

2022年，中国腐蚀与防护学会科学技术一等奖；

2021年，中国腐蚀与防护学会科学技术一等奖；

部分授权专利信息：

1. 刘超、孙亮、李晓刚 等；一种低成本高强韧低密度耐腐蚀的桥梁钢及其制备方法；ZL202510569920.3

2. 刘超、车智超、李晓刚 等；一种高温耐点蚀不锈钢及其制备方法；ZL202510265387.1

3. 刘超、陈天奇、李晓刚 等；一种抗氢脆Cr-Mo合金钢及其制备方法；ZL202411295809.1

4. 刘超、车智超、李晓刚 等；一种抗点蚀316L不锈钢及其制备方法；ZL202311725584.4

5. 刘超、李晓刚、程学群 等；耐蚀低密度钢及其制备方法；ZL202210127289.8

6. 刘超、张沙沙、李晓刚 等；抗点蚀马氏体硬化不锈钢；ZL202211050539.9

7. 刘超、李晓刚、程学群 等；耐腐蚀抗震钢材、钢筋及其制备方法；ZL202111046964.6

代表性专著：

Chao Liu, Xiaogang Li. Steel Corrosion and Metallurgical Factors: Laws and Mechanisms[M]. John Wiley & Sons, 2025.

Chao Liu, Bingqin Wang, Xiaogang Li, Shasha Zhang, Zhong Li. Marine Corrosion of Steels: Mechanisms and AI-Driven Solutions[M]. John Wiley & Sons, 2026.

部分代表性论文：

1. Che, Z., Wu, W., Liu, W., Yang, S., Wang, B., Cheng, X., ... & Liu, C. Positive Enhancement Mechanism of Al Element on the Corrosion Resistance of 15-5PH Stainless Steel in Sea Water Heat Exchanger Environment. Corrosion Science, 2026, 113726.

2. Chen, T., Li, C., Cai, X., Wu, F., Wang, Z., Cheng, X., ... & Liu, C.. Deterioration mechanism of passivation behavior of ductile iron induced by shrinkage defects in simulated concrete pore solution. Journal of Materials Science & Technology, 2025, 236: 136-149.

3. Chen, T., Wu, F., Li, C., Cheng, X., Li, X., Chen, Y., & Liu, C.. Understanding the mechanism of shrinkage defects on corrosion kinetics of ductile iron. Corrosion Science, 2025, 256: 113168.

4. Chen, T., Zhou, X., Zhang, S., Du, Y., Chen, J., Cheng, X., ... & Liu, C.. Insights into multiple coupling mechanisms of SO42−/Cl− and Cr/RE elements on the corrosion resistance of rebar in simulated carbonated concrete pore solution. Construction and Building Materials, 2025, 485: 141957.

5. Chen, T., Wu, F., Li, Q., Yang, G., Chen, Y., Liu, C., ... & Li, X.. Comparative study on corrosion resistance of carbon steel and ductile iron: implications for the development of corrosion-resistant steels. Corrosion Science, 2025: 113127.

6. Che, Z., Xue, H., Liu, J., Zhou, X., Liu, W., Yang, S., ... & Liu, C. A novel understanding of dislocation density effect on the corrosion resistance of 316L stainless steel with passive film nucleation growth kinetic calculation. Corrosion Science, 2025, 248: 112810.

7. Xu, D., Chen, T., Yang, G., Sun, L., Xu, C., Liu, C., ... & Li, X.. Insight into the effect of oxygen content on the corrosion behavior of X70 pipeline steel in a typical simulated soil solution by dissolution-diffusion-deposition model. Corrosion Science, 2024, 240: 112478.

8. Chen, T., Shang, T., Jiang, G., Teng, H., Liu, W., He, X., ... & Liu, C.. Effect of SO2 and NH3 on the corrosion failure of Zn-Al-Mg coatings. Surface and Coatings Technology, 2024, 493: 131244.

9. Jiang, Z., Chen, T., Che, Z., Liu, C., Yan, Y., Huang, F., ... & Li, X. Effect of Ca-Mg microalloying on corrosion behavior and corrosion resistance of low alloy steel in the marine atmospheric environment. Corrosion Science, 2024, 234: 112134.

10. Liu, T., Chen, T., Zhou, X., Sun, L., Yang, W., Liu, C., ... & Li, X. Investigation of Cr and rare earth (RE) on the corrosion resistance of HRB400 rebar in simulated concrete pore solutions containing chloride and sulfate ions. Construction and Building Materials, 2024, 423: 135935.

11. Wang, B., Mu, Y., Shen, F., Zhu, R., Li, Y., Liu, C., ... & Li, X.. Identification of Corrosion Factors in Blast Furnace Gas Pipe Network with Corrosion Big Data Online Monitoring Technology. Corrosion Science，2024，230，11190.

12. Li, N., Wang, B., Liu, T., Liu, C., Che, Z., Chen, T., ... & Li, X.. Revealing the coupling of multiple corrosion behaviors in the corrosion process of titanium-steel composites in marine environment. Corrosion Science, 2024, 233: 112107.

13. Zhang, T., Hao, L., Jiang, Z., Liu, C., Zhu, L., Cheng, X., ... & Li, X.. Investigation of rare earth (RE) on improving the corrosion resistance of Zr-Ti deoxidized low alloy steel in the simulated tropic marine atmospheric environment. Corrosion Science, 2023: 111335.

14. Yang, S., Che, Z., Liu, C., Liu, W., Li, J., Cheng, X., & Li, X.. Mechanism of the dual effect of Te addition on the localised corrosion resistance of 15-5PH stainless steel. Corrosion Science, 2023: 110970.

15. Zhang, T., Li, Y., Li, X., Liu, C., Yang, S., Yang, Z., & Li, X.. Integral effects of Ca and Sb on the corrosion resistance for the high strength low alloy steel in the tropical marine environment. Corrosion Science, 2022, 208: 110708.

16. Liu, C., Revilla, R. I., Li, X., Jiang, Z., Yang, S., Cui, Z., ... & Li, X.. New insights into the mechanism of localised corrosion induced by TiN-containing inclusions in high strength low alloy steel. Journal of Materials Science & Technology, 2022, 124: 141-149.

17. Liu, C., Li, X., Revilla, R. I., Sun, T., Zhao, J., Yang, S., ... & Li, X. . Towards a better understanding of localised corrosion induced by typical non-metallic inclusions in low-alloy steels. Corrosion Science, 2021, 179: 109150.

18. Liu, C., Jiang, Z., Zhao, J., Cheng, X., Liu, Z., Zhang, D., & Li, X. . Influence of rare earth metals on mechanisms of localised corrosion induced by inclusions in Zr-Ti deoxidised low alloy steel. Corrosion Science, 2020, 166: 108463.

19. Liu, C., Revilla, R. I., Zhang, D., Liu, Z., Lutz, A., Zhang, F., ... & Terryn, H.. Role of Al2O3 inclusions on the localized corrosion of Q460NH weathering steel in marine environment. Corrosion Science, 2018, 138: 96-104.

20. Liu, C., Revilla, R. I., Liu, Z., Zhang, D., Li, X., & Terryn, H.. Effect of inclusions modified by rare earth elements (Ce, La) on localized marine corrosion in Q460NH weathering steel. Corrosion Science, 2017, 129: 82-90.