1. 主持的科研项目: [1] 基于深冷轧制的高强度高熵合金氢脆行为研究,2019.05-2022.04,20万,在研,上海市科委 2. 所发表的学术论文: 第一作者: [1] Min Liu, et. al, Microstructures and hardnesses of CoCr0.5FexNi2.5 high entropy alloys with equal valence electron concentration,Journal of Alloys and Compounds,824 (2020) 153881. [2] M. Liu, et. al, Influence of cooling path after rolling on sulfide stress cracking behavior for casing steel,International Journal of Hydrogen Energy, 45 (2020) 1114-1124. [3] M. Liu, et. al., Effect of microstructure and crystallography on sulfide stress cracking in API-5CT-C110 casing steel, Materials Science and Engineering: A, 671 (2016) 244-253. [4] M. Liu, et. al, Effect of quenching and tempering process on sulfide stress cracking susceptibility in API-5CT-C110 casing steel, Materials Science and Engineering: A, 688 (2017) 378-387 [5] M. Liu, et. al, Microstructure evolution and mechanical properties in 1Cr low alloy steel with different heat treatments, Materials Science and Engineering: A, 705 (2017) 291-299 通讯作者: [1] M. Luo, M. Liu*, Effect of tempering temperature at high temperature zone on sulfide stress cracking behavior for casing steel, Engineering Failure Analysis, 105 (2019) 227-236. [2] Song Ding, Min Liu*, Structural and Magnetic Characterization of Fe-Based Amorphous Alloy Prepared by Microwave Annealing Treatment. Journal of Electronic Materials, 2020, 49: 2402-2405. [3] Li, Fangjie, Min Liu*, A New Criterion for Prediction of Phase Stability in Al‐Containing High Entropy Alloys. Physica Status Solidi B-Basic Solid State Physics, 2020, p. 2000470. 非第一作者和通讯作者: [1] X.T. Wang, M. Liu, et. al, Effects of chromium and tungsten on sulfide stress cracking in high strength low alloy 125 ksi grade casing steel, Corrosion Science, 160 (2019) 108-163. [2] Z.H. Zhang, M. Liu, et. al, A systematical analysis respect to multiple hydrogen traps influencing sulfide stress cracking behavior of API-5CT-C110 casing steel, Materials Science and Engineering: A, 721 (2018) 81-88. [3] C.H. Wang, M. Liu, et. al, The effects of α ″and ω phases on the superelasticity and shape memory effect of binary Ti-Mo alloys, Journal of Alloys and Compounds, 720 (2017) 488-496. [4] C.H. Wang, C.D. Yang, M. Liu, et. al, Martensitic microstructures and mechanical properties of as-quenched metastable β-type Ti–Mo alloys, Journal of Materials Science, 51 (2016) 6886-6896. [5] R.Q. Lin, C. Fu, M. Liu, et. al, Microstructure and oxidation behavior of Al + Cr co-deposited coatings on nickel-based superalloys, Surface and Coatings Technology, 310 (2017) 273-277. [6] Y. Liu, C.D. Yang, M. Liu, et. al, Effects of microstructure and crystallography on mechanical properties of cold-rolled SAE1078 pearlitic steel, Materials Science and Engineering: A, 709 (2018) 115-124. [7] Z. Chen, Y. Liu, H. Jiang, M. Liu, et. al, Microstructures and mechanical properties of Mn modified, Ti-Nb-based alloys, Journal of Alloys and Compounds, 723 (2017) 1091-1097. [8] G.H. Cao, T.Y. Sun, C.H. Wang, X. Li, M. Liu, et. al, Investigations of γ′, γ″ and δ precipitates in heat-treated Inconel 718 alloy fabricated by selective laser melting, Materials Characterization, 136 (2018) 398-406. |