[1] T.R. Li, G.H. Liu, M. Xu, et al. Effects of hot-pack rolling process on microstructure, high-temperature tensile properties, and deformation mechanisms in hot-pack rolled thin Ti-44Al-5Nb-(Mo, V, B) sheets, Materials Science and Engineering: A, 2019, 764, JCR 1 区, 中科院一区, IF=4.62 [2] T.R. Li, G.H. Liu, M. Xu, et al. Wang, High temperature deformation and control of homogeneous microstructure during hot pack rolling of Ti-44Al-5Nb-(Mo, V, B) alloys: The impact on mechanical properties, Materials Science and Engineering: A, 2019, 751: 1-9, JCR 1 区, 中科院一区, IF=4.62 [3] G.H. Liu, T.R. Li*, X.Q. Wang, et al. Effect of alloying additions on work hardening, dynamic recrystallization, and mechanical properties of Ti-44Al-5Nb-1Mo alloys during direct hot-pack rolling, Materials Science and Engineering: A, (* corresponding author), 2020, 773, JCR 1 区, 中科院一区, IF=4.62 [4] T.R. Li, G.H. Liu, M. Xu, et al. Flow Stress Prediction and Hot Deformation Mechanisms of Ti-44Al-5Nb-(Mo, V, B) Alloy, Materials, 2018, 11: 2044-2060, JCR 2 区, 中科院三区, IF=3.057 |
[5] T.R. Li, G.H. Liu, M. Xu, et al. Effects of hot-pack rolling process on microstructure, high-temperature tensile properties, and deformation mechanisms in hot-pack rolled thin Ti-44Al-5Nb-(Mo, V, B) sheets, Materials Science and Engineering: A, 2019, 764, JCR 1 区, 中科院一区, IF=4.62 [6] T.R. Li, G.H. Liu, M. Xu, et al. Wang, High temperature deformation and control of homogeneous microstructure during hot pack rolling of Ti-44Al-5Nb-(Mo, V, B) alloys: The impact on mechanical properties, Materials Science and Engineering: A, 2019, 751: 1-9, JCR 1 区, 中科院一区, IF=4.62 [7] G.H. Liu, T.R. Li*, X.Q. Wang, et al. Effect of alloying additions on work hardening, dynamic recrystallization, and mechanical properties of Ti-44Al-5Nb-1Mo alloys during direct hot-pack rolling, Materials Science and Engineering: A, (* corresponding author), 2020, 773, JCR 1 区, 中科院一区, IF=4.62 [8] T.R. Li, G.H. Liu, M. Xu, et al. Flow Stress Prediction and Hot Deformation Mechanisms of Ti-44Al-5Nb-(Mo, V, B) Alloy, Materials, 2018, 11: 2044-2060, JCR 2 区, 中科院三区, IF=3.057 [9] T.R. Li, G.H. Liu, M. Xu, et al. Hot Deformation Behavior and Microstructural Characteristics of Ti–46Al–8Nb Alloy, Acta Metallurgica Sinica (English Letters), 2018, 31(9): 933-944, JCR 1 区, 中科院二区, IF=2.09 [10] 李天瑞, 刘国怀, 于少霞, 等.直接包套轧制铸态Ti-46Al-8Nb合金的组织特征及热变形机制, 金属学报, 2020(08): 1091-1102, JCR 2 区, 中科院三区, IF=0.938 [11] 李天瑞, 刘国怀, 徐莽, 等. Ti-43Al-4Nb-1.5Mo合金包套锻造与热处理过程的微观组织及高温拉伸性能, 金属学报, 2017(09): 33-42, JCR 2 区, 中科院三区, IF=0.938 [12] T.R. Li, G.H. Liu, R.Q. Guo, et al. Hot-pack Accumulative Roll-bonding (HP-ARB) Process of Ti-44Al-5Nb-1Mo-(V, B) Alloys, 2019 International Conference on Materials, Mechanical, Electrical, Automation and Control Engineering (MMEACE 2019), 国际会议论文EI, 2019.11.19, Accepted [13] 刘国怀, 李天瑞, 徐莽, 等. 累积叠轧TC4钛合金的组织演化及力学性能, 金属学报, 2017(09): 16-24, JCR 2 区, 中科院三区, IF=0.938 [14] G.H. Liu, T.R. Li, T.L. Fu, et al. Morphology and competitive growth during the development of the parallel lamellar structure by self-seeding in directionally solidified Ti-50Al-4Nb alloy, Journal of Alloys and Compounds, 2016, 682: 601-609, JCR 1区, 中科院二区, IF=4.12 |
