Personal profile：

Dr. Chao Liu, was born in 1988. He graduated from the institute of materials science and engineering, university of science and technology Beijing in 2019 with a PhD. He entered the institute for advanced materials technology of university of science and technology Beijing in February 2019 to engage in postdoctoral research. He mainly devotes to the research on the theory and application of micro-electrochemical technology in localized corrosion of materials. He has participated in the research under supported of national 973 project, the national natural science foundation of china, the national science and technology platform, and the independent research program of the Ministry of Education, etc.. He has published a number of papers in the high level journals like Corrosion Science、Journal of The Electrochemical Society、Journal of Materials Engineering and Performance、Metallurgical and Materials Transactions B, etc.. He has participated in the setting and revision of 47 group standards. In 2017, he won the second prize of the 15th national youth corrosion and protection science and technology paper evaluation conference.

Research direction：

1. Micro-electrochemical detection technology of localized corrosion

2. Mechanism of localized corrosion induced by microstructure

3. Development of corrosion resistant steel and mechanism research of corrosion resistant

Scientific research achievement :

Part of the paper

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

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

3.  Liu, C., Yang, S., Li, J., Zhu, L., & Li, X. (2016). Motion behavior of nonmetallic inclusions at the interface of steel and slag. Part I: Model development, validation, and preliminary analysis. Metallurgical and Materials Transactions B, 47(3), 1882-1892.

4.  Liu, C., Cheng, X., Dai, Z., Liu, R., Li, Z., Cui, L., ... & Ke, L. (2018). Synergistic Effect of Al2O3 Inclusion and Pearlite on the Localized Corrosion Evolution Process of Carbon Steel in Marine Environment. Materials, 11(11), 2277.

5.  Zhao, T., Liu, Z., Du, C., Liu, C., Xu, X., & Li, X. (2018). Modeling for corrosion fatigue crack initiation life based on corrosion kinetics and equivalent initial flaw size theory. Corrosion Science, 142, 277-283.

6.  Cui, Z., Wang, L., Zhong, M., Ge, F., Gao, H., Man, C., ... & Wang, X. (2018). Electrochemical Behavior and Surface Characteristics of Pure Titanium during Corrosion in Simulated Desulfurized Flue Gas Condensates. Journal of The Electrochemical Society, 165(9), C542-C561.

7.  Yang, S., Li, J., Liu, C., Sun, L., & Yang, H. (2014). Motion behavior of nonmetal inclusions at the interface of steel and slag. Part II: Model application and discussion. Metallurgical and Materials Transactions B, 45(6), 2453-2463.

8.  Zhao, T., Liu, Z., Chao, L., Dai, C., Du, C., & Li, X. (2018). Variation of the Corrosion Behavior Prior to Crack Initiation of E690 Steel Fatigued in Simulated Seawater with Various Cyclic Stress Levels. Journal of Materials Engineering and Performance, 27(9), 4921-4931.

9. T/CSTM 00046.1-2018/T/CSCP 0035.1-2018 Corrosion test of low alloy structure steels Part 1: General guidance

10. T/CSTM 00046.2-2018/T/CSCP 0035.2-2018 Corrosion test of low alloy structure steels Part 2: Corrosion tests in simulated atmosphere

11. T/CSTM 00046.3-2018/T/CSCP 0035.3-2018 Corrosion test of low alloy structure steels Part 3: General rule of corrosion tests in artificial marine environment

12. T/CSTM 00046.12-2018/T/CSCP 0035.12-2018 Corrosion test of low alloy structure steels Part 12: The test method of galvanic corrosion

13. T/CSTM 00046.16-2018/T/CSCP 0035.16-2018 Corrosion test of low alloy structure steels Part 16: The test method of localized electrochemical corrosion