[1] Liu Zhiyang*, Dong Zejiao*, Tao Zhou, et al. Water vapor diffusion models in asphalt mortar considering adsorption and capillary condensation [J]. Construction and Building Materials, 2021(308): 15.
[2] Liu Zhiyang, Cao Liping, Zhou Tao, et al. Multiscale investigation of moisture-induced structural evolution in asphalt–aggregate interfaces and analysis of the relevant chemical relationship using atomic force microscopy and molecular dynamics[J]. Energy & Fuels 2020 34 (4), 4006-4016
[3] Liu Zhiyang, Wang Haipeng, Gong Xiangbing, et al. Stiffening and toughening of asphalt mastic induced by bitumen–mineral selective molecular adsorption and nanostructural reconstruction [J]. Sustainability, 2023, 15, 4398
[4] Liu Zhiyang, Wang Peng, Huang Zhenfu, et al. Nano-micelle formation and aggregation in sbs-modified asphalt induced by π-π interaction using molecular dynamics [J]. Materials & Design
[5] Dong Zejiao*, Liu Zhiyang, Yang Chen, et al. Viscosity characterization of confined bitumen considering microaggregate‐bitumen interactions. Computer-Aided Civil and Infrastructure Engineering, 2020; 1-15.
[6] Dong Zejiao*, Liu Zhiyang, Wang Peng, et al. Nanostructure characterization of asphalt-aggregate interface through molecular dynamics simulation and atomic force microscopy[J]. Fuel, 2017, 189: 155-163.
[7] Dong Zejiao*, Liu Zhiyang, Wang Peng, et al. Modeling asphalt mastic modulus considering substrate–mastic interaction and adhesion[J]. Construction and Building Materials, 2018: 324-333.
[8] Liu Zhiyang*, Dong Zejiao*, Gong Xiangbing, at al. Micromechanics analysis of viscoelastic properties for asphalt mastic under a long-term water exposure. 101st annual Meeting of the Transportation Research Board, Washington, D.C. 2022.
[9] Dong, Zejiao*, Liu Zhiyang. Effects of aggregate mineralogy on rheology of asphalt mastics. 96th annual Meeting of the Transportation Research Board, Washington, D.C. 2017.
[10] Zhang Yuan, Leng Zhen, Dong Zejiao*, Liu Zhiyang, Zeyu Zhang, and Zhifei Tan. Performance verification of various bulk density measurement methods for open-and gap-graded asphalt mixtures using X-ray computed tomography[J]. Construction and Building Materials 158 (2018): 855-863.
[11] Wang Peng, Dong Zejiao*, Tan Yiqiu, Liu Zhiyang. Investigating the interactions of the saturate, aromatic, resin, and asphaltene four fractions in asphalt binders by molecular simulations. Energy & Fuels, 2015, 29(1):112–121.
[12] Wang Peng, Dong Zejiao*, Tan Yiqiu, Liu Zhiyang. Anti-ageing properties of styrene–butadiene–styrene copolymer-modified asphalt combined with multi-walled carbon nanotubes[J]. Road Materials and Pavement Design, 2017, 18(3): 533-549.
[13] Wang Peng, Dong Zejiao*, Tan Yiqiu, Liu Zhiyang. Identifying the rheological properties of polymer-modified bitumen based on its morphology. Road Materials and Pavement Design, 2017, 18(S3): 249-258.
[14] Wang Peng, Dong Zejiao*, Tan Yiqiu, Liu Zhiyang. Effect of multi-walled carbon nanotubes on the performance of styrene-butadiene- styrene copolymer modified asphalt, Materials and Structures, 2017, 50(1): 17.
[15] Wang Peng, Dong Zejiao*, Liu Zhiyang. Influence of carbon nanotubes on morphology of asphalts modified with styrene–butadiene–styrene[J]. Transportation Research Record: Journal of the Transportation Research Board, 2017 (2632): 130-139.
[16] 王鵬,董澤蛟*,譚憶秋,劉志楊. 基于分子模拟探究瀝青蜂窩結構的成因[J]. 中國公路學報, 2016, 29(3):9-16.
[17] Dong Zejiao*, Gong Xiangbing, Liu Zhiyang. Rheological characterization of SBS modified asphalt utilizing different modified parallel plates. 94th annual Meeting of the Transportation Research Board, Washington, D.C., 2015.
[18] 董澤蛟*, 肖峰, 劉志楊, 周濤. 基于FEM的無機結合料穩定類基層瀝青路面凍融影響評價試驗設計. 世界交通大會, 北京, 2018.