1、期刊论文(#为通讯作者)
[1] Yunhui Sun, Jiajun Jiao, Yi An, Xiaoliang Wang#, Qingquan Liu. Reconstruction of the internal volume fraction for particle-liquid system from imaging indicators by refractive index matching. Acta Mechanica Sinica. 2024, 40: 323233.
[2] Wangxin Yu, Xiaoliang Wang#, Qingquan Liu, Xuedong Chen, Huaning Wang. Flow pattern of fast granular flow impacting a granular deposit. Powder Technology. 2023, 430: 118989.
[3] Yunhui Sun, Jiajun Jiao, Yi An, Xiaoliang Wang#, Qingquan Liu#. Experimental study on internal flow structure and dynamics of dense liquid-particle flow down inclined channel. Experiments in Fluids. 2023, 64(9): 150.
[4] Can Huang, Chao Hu, Yi An, Chuanqi Shi, Chun Feng, Huaning Wang, Qingquan Liu#, Xiaoliang Wang#. Numerical simulation of the large-scale Huangtian (China) landslide-generated impluse waves by a GPU-accelerated three-dimensional soil-water coupled SPH model. Water Resource Research. 2023, 59, e2022WR034157.
[5] Li Ge, Li Libin, Liu Qingquan, Feng Chun, Wang Xiaoliang#. A unified consistent source term computational algorithm for the γ-based compressible multifluid flow model. Computers and Fluids. 2023, 259: 105899.
[6] Enwei Zhang, Wangxia Wu, Qingquan Liu#, Xiaoliang Wang#. Effects of vortex formation and interaction on turbulent mass transfer over a two-dimensional wavy wall. Physical Review Fluids. 2022, 7:114607.
[7] 李立彬, 喻鑫龙, 刘青泉, 王晓亮#. 基于反应欧拉方程投影算法的广域尺度气体爆炸数值模拟研究. 中国科学:技术科学. 2023. 53(4): 601-614.
[8] Can Huang, Yunhui Sun, Yi An, Chuanqi Shi, Chun Feng, Qingquan Liu, Xiufeng Yang, Xiaoliang Wang#. Three-dimensional simulations of large-scale long run-out landslides with a GPU-accelerated elasto-plastic SPH model. Engineering Analysis with Boundary Elements. 2022, 145: 132-148.
[9] Wang Xiaoliang, Yang S, Yu WX, Yang XF, Liu QQ#. Runout and deflection of granular flow on steep terrains with an array of obstacles. European Journal of Mechanics –B Fluids. 2022, 94: 37-49.
[10] Hu Chao, Wang Xiaoliang#, Liu Qingquan#. Characteristics of iceberg calving-generated waves based on three-dimensional SPH simulations. Coastal Engineering. 2022, 173:104090.
[11] Hu Chao, Liu Qingquan# , Wang Xiaoliang#. Numerical study of waves generated during iceberg calving in sliding mode. Ocean Engineering. 2022, 246:110622
[12] Wang Xiaoliang, Li G, Liu QQ #. An updated critical state model by incorporating inertial effects for granular material in solid-fluid transition regime. Granular Matter 2022, 24: 38.
[13] Zhang EW, Wang XL, Liu QQ#. Numerical investigation on the temporal and spatial statistical characteristics of turbulent mass transfer above a two-dimensional wavy wall. International Journal of Heat and Mass Transfer. 2022, 184: 122260.
[14] 杨肃,张会琴,余王昕,程鹏达,刘青泉,王晓亮#. 基于沿程坐标积分模式的颗粒流与结构物阵列相互作用的数值模拟. 力学学报. 2021, 53(12): 3399-3412.
[15] Sun YH, Zhang WT, An Y, Liu QQ#, Wang XL#. Experimental investigation of immersed granular collapse in viscous and inertial regimes. Physics of Fluids. 2021, 33: 103317.
[16] Liu QQ, Pan MH, Wang XL#, An Y. A two-layer model for landslide generated impulse wave: Simulation of the 1958 Lituya bay landslide impact wave from generation to long-duration transport. Advances in Water Resources 2021, 154: 103989.
[17] Zhang EW, Wang XL, Liu QQ#. Effects of the spanwise heterogeneity of a three-dimensional wavy wall on momentum and scalar transport. Physics of Fluids 2021, 33(5): 055116.
[18] 陈歆怡, 王晓亮#, 刘青泉, 张静. 滚波演化中聚合过程的数值模拟研究.力学学报 2021. 53(5): 1457-1470.
[19] Wang XL, Shi CQ, Liu QQ#, An Y. Numerical study on near-field characteristics of landslide-generated impulse waves in channel reservoirs. Journal of Hydrology 2021, 595: 126012.
[20] Wang XL, Liu QQ#. Modeling shallow geological flows on steep terrains using a specific differential transformation. Acta Mechanica 2021, 232: 2379-2394.
[21] Wang XL #, Zhang Z, Li JC #, Liu QQ. Mesoscale analysis of the suction stress characteristic curve for unsaturated granular materials. Particuology 2021, 56: 183-192.
[22]Chen XY, Wang XL, Liu QQ #. Numerical study of roll wave characteristics based on Navier-Stokes equations: A two-dimensional simulation. Journal Engineering Mechanics 2021,147(2):0402149.
[23] Yang S, Wang XL#, Liu QQ, Pan MH. Numerical simulation of fast granular flow facing obstacles on steep terrains. Journal of Fluids and Structures 2020, 99: 103162.
[24] Sun YH, Zhang WT, Wang XL, Liu QQ #. Numerical study on immersed granular collapse in viscous regime by particle-scale simulation. Physics of Fluids 2020, 32: 073313.
[25] Zhang WT, An Y, Liu QQ #, Wang XL, Sun Y.H. Evolution of Energy in Submerged Granular Column Collapse. Chinese Physics Letters 2020, 37(7): 074502.
[26] 黄灿, 刘青泉, 王晓亮#. 梯级溃坝洪水洪峰增强机制. 力学学报 2020, 52(3): 645-655.
[27] Wang XL #, Zhang Z, Li JC #. Triaxial behavior of granular material under complex loading path by a new numerical true triaxial engine. Advanced Powder Technology 2019, 30 (4): 700-706.
[28] Wang XL, Li JC #. A new solver for granular avalanche simulation: Indoor experiment verification and field scale case study. Science China Physics Mechanics & Astronomy 2017, 60 (12): 124712.
[29] Wang XL, Li JC#. A novel liquid bridge model for estimating SWCC and permeability of granular material. Powder Technology 2015, 275: 121-130.
[30] Wang XL; Li JC#. On the degradation of granular materials due to internal erosion. Acta Mechanica Sinica 2015, 31 (5): 685-697.
[31] Wang XL; Li JC#. Simulation of triaxial response of granular materials by modified DEM. Science China Physics Mechanics & Astronomy 2014, 57 (12): 2297-2308.
[32] Wang XL; Chen S#. Simulation of vapor-liquid coexistence using dissipative particle dynamics. Acta Physica Sinica 2010, 59 (10): 6778-6785.
