1Ding J, Zhang M, Liang Y, et al.Enhanced high-temperature tensile property by gradient twin structure of duplex high-Nb-containing TiAl alloy[J].Acta Materialia, 2018, 161: 1-11.(影响因子:7.656,1区) 2Ding J, Zhang M, Ye T, et al. Microstructure stability and micro-mechanical behavior of as-cast gamma-TiAl alloy during high-temperature low cycle fatigue[J].Acta Materialia, 2018, 145: 504-515.(影响因子:7.656,1区) 3Ding J, Wu X, Shen X, et al. Synthesis and textural evolution of mesoporous Si3N4aerogel with high specific surface area and excellent thermal insulation property via the urea assisted sol-gel technique[J].Chemical Engineering Journal, 2020, 382: 122880.(影响因子:10.652,1区) 4Ding J, Wu X, Shen X, et al. A promising form-stable phase change material composed of C/SiO2aerogel and palmitic acid with large latent heat as short-term thermal insulation[J].Energy, 2020, 210: 118478.(影响因子:6.082,1区) 5Ding J, Liang Y, Xu X, et al. Cyclic deformation and microstructure evolution of high Nb containing TiAl alloy during high temperature low cycle fatigue[J].International Journal of Fatigue, 2017, 99: 68-77.(影响因子:4.369,1区) 6Ding J, Wu X, Shen X, et al. Form-stable phase change material embedded in three-dimensional reduced graphene aerogel with large latent heat for thermal energy management[J].Applied Surface Science, 2020, 534: 147612.(影响因子:6.182,1区) 7Ding J, Zhong K, Liu S, et al. Flexible and super hydrophobic polymethylsilsesquioxane based silica aerogel for organic solvent adsorption via ambient pressure drying technique[J].Powder Technology, 2020, 373: 716-726.(影响因子:4.142) 8Ding J, Lin J, Zhang M, et al. High-temperature torsion induced gradient microstructures in high Nb-TiAl alloy[J].Materials Letters, 2017, 209: 193-196.(影响因子:3.204) 9Ding J,Shi S, Dong Z, et al. Cyclic deformation and lattice strain distribution of high Nb containing TiAl alloy[J].Materials Science and Technology, 2020, 36(14): 1507-1515.(影响因子:1.835) 10Ding J,Huang S, Dong Z, et al. Thermal Stability and Lattice Strains Evolution of High Nb containing TiAl Alloy Under Low Cycle Fatigue Loading[J].Advanced Engineering Materials, 2021. DOI: 10.1002/adem.202001337.(影响因子:3.217,3区) 11Shi Shan, Deng Qinghua, Zhang Hang, Feng Liang, Xu Xiangjun,Ding J*, Hui Chang, Lian Zhou. Microstructure stability and damage mechanisms in anα/βTi-6Al-4V-0.55Fe alloy during low cycle dwell-fatigue at room temperature[J].International Journal of Fatigue, 2022 (15): 106585.
|