Journal-2024

3 高田创，高建宝，李谦，等, 机器学习驱动难熔高熵合金设计的现状与展望, 材料工程, 52(1):27-44

5 FU H, GAO T, GAO J, et al., Breaking hardness and electrical conductivity trade-off in Cu-Ti alloys through machine learning and Pareto front, Materials Research Letters, 12(8):580-589

6 LI Z, JIANG X, WANG Z, et al., Accelerating lPBF process optimisation for NiTi shape memory alloys with enhanced and controllable properties through machine learning and multi-objective methods, Virtual and Physical Prototyping, 19(1):e2364221

7 LONG Y, ZHONG J, ZHANG T, et al., Multiscale Simulation of Microstructure Evolution during Preparation and Service Processes of Physical Vapor Deposited c-TiAlN Coatings, Computers, Materials & Continua, 79(3):580-589

8 Chen S, Tang Q, et al., High-throughput screening of multicomponent alloy compositions with optimal mechanical properties using two-step diffusion multiple: Demo in Al–Co–Cr–Fe–Ni–Ti high-entropy superalloys, Materials Science and Engineering, A910:146909

9 Zhang T, Zhong J, et al., Multi-objective optimization assisting three-dimensional quantitative Cahn-Hilliard simulations of microstructure evolution in Fe-Cr alloys during spinodal decomposition, Computational Materials Science, 244:113260

10 Li Z, Zhong J, et al., Toward additive manufactured crack-free NiTiCu shape memory alloys with low-hysteresis and tailorable phase transition behavior supported by theoretical design, Additive Manufacturing, 92:104386

11 Zeng L, Jin Y, Gao J, Yi W, et al., Achieving simultaneous improvement in strength and ductility in Al–Si–Mg–Ce alloy through synergistic morphology modification of eutectic (Si) and Al2Si2Ce phases by Sr addition, Journal of Materials Research and Technology, 33:975-981

12 Gao T, Gao J, Yang S, et al., Data-driven design of novel lightweight refractory high-entropy alloys with superb hardness and corrosion resistance, npj Computational Materials, 10(1):256