期刊论文

 SCI期刊论文(*为通讯作者)

 

  1. Jiankun Zhang, Haihu Liu*, 2022, “Effect of blade tip pattern on blade load and vibration characteristics of a twin-stage axial flow fan”, Journal of Mechanical Science and Technology, in press.
  2. Xitong Zhang, Jiangang Zhang, Haihu Liu*, Pan Jia, 2022, “Rayleigh–Plateau Instability of a Particle-Laden Liquid Column: A Lattice Boltzmann Study”, Langmuir, 38(11):3453-3468.

  3. Jinggang Zhang, Xitong Zhang, Wei Zhao, Haihu Liu*, Youhua Jiang, 2022, “Effect of surfactants on droplet generation in a microfluidic T-junction: A lattice Boltzmann study”, Physics of Fluids, 34: 042121.

  4. Dong Wang, Ningning Wang, Haihu Liu*, 2022, “Droplet deformation and breakup in shear-thinning viscoelastic fluid under simple shear flow”, Journal of Rheology, 66(3): 585-603.

  5. Fei Jiang, Haihu Liu, Xian Chen, Takeshi Tsuji, 2022, “A coupled LBM-DEM method for simulating the multiphase fluid-solid interaction problem”, Journal of Computational Physics, 454: 110963.

  6. Muhammad Sami Rashad, Haihu Liu*, Shan Ali Khan, 2022, “Numerical Simulation for Bioconvection of Unsteady Stagnation Point Flow of Oldroyd-B Nanofluid with Activation Energy and Temperature-Based Thermal Conductivity Past a Stretching Disk”, Computer Modeling in Engineering & Sciences, 130(1):233-254.

  7. Jiangang Zhang, Xitong Zhang, Ningning Wang, Haihu Liu*, Guang Xi, 2021, “Lattice Boltzmann modeling of particle dynamics in rotating coordinate system”,  Physics of Fluids, 33:123316.

  8. Sheng Li, Haihu Liu*, Jinggang Zhang, Fei Jiang, Guang Xi, 2021, “Modeling of three-phase displacement in three-dimensional irregular geometries using a lattice Boltzmann method”, Physics of Fluids, 33:122108.

  9. Jinggang Zhang, Haihu Liu*, Bei Wei, Jian Hou, Fei Jiang, 2021, “Pore-Scale Modeling of Two-Phase Flows with Soluble Surfactants in Porous Media”, Energy & Fuels, 35(23):19374-19388.

  10. Zhenhan Diao, Sheng Li, Wei Liu, Haihu Liu*, Qingfeng Xia, 2021, “Numerical study of the effect of tortuosity and mixed wettability on spontaneous imbibition in heterogeneous porous media”, Capillarity, 4(3): 50-62.
  11. Feng Liu, Kai Yin, Haihu Liu*, 2021, "A microfluidic synthesis method for preparation and regulation of 3-aminophenol formaldehyde resin spheres", Reactive and Functional Polymers, 165:104973.
  12. Sheng Li, Yang Lu, Fei Jiang, Haihu Liu*, 2021, "Lattice Boltzmann simulation of three-phase flows with moving contact lines on curved surfaces", Physical Review E, 104:015310.
  13. Haihu Liu*, Shilin Sun, Rui Wu, Bei Wei, Jian Hou*, 2021, “Pore-Scale Modeling of Spontaneous Imbibition in Porous Media Using the Lattice Boltzmann Method”, Water Resources Research, 57(6):e2020WR029219.
  14. Sheng Li, Fei Jiang, Bei Wei, Jian Hou, Haihu Liu*, 2021, “Prediction of three-phase relative permeabilities of Berea sandstone using lattice Boltzmann method”, Physics of Fluids, 33(6):063302.
  15. Jinggang Zhang, Haihu Liu*, Xitong Zhang, 2021, "Modeling the deformation of a surfactant-covered droplet under the combined influence of electric field and shear flow", Physics of Fluids, 33(4): 042109.
  16. Qingqing Gu, Haihu Liu*, Lei Wu*, 2021, “Preferential imbibition in a dual-permeability pore network”, Journal of Fluid Mechanics,  915:A138.
  17. Min Li, Yang Zhang, Haihu Liu*, Yuan Wang, Bin Yang, 2021, "Vapor condensation in Rayleigh-Bénard convection", Physics of Fluids, 33:012109.
  18. Haihu Liu*, Yang Lu, Sheng Li, Yuan Yu, Kirti Chandra Sahu, 2021, "Deformation and breakup of a compound droplet in three-dimensional oscillatory shear flow", International Journal of Multiphase Flow, 134:103472.
  19. Xitong Zhang, Haihu Liu*, Ya Zhang, Liang Wang, 2020, “Direct numerical simulation of the sedimentation of a particle pair in a shear-thinning fluid”, Physical Review Fluids, 5(1):014304.
  20. Haihu Liu*, Jinggang Zhang, Yan Ba, Ningning Wang, Lei Wu, 2020, "Modelling a surfactant-covered droplet on a solid surface in three-dimensional shear flow", Journal of Fluid Mechanics, 897:A33.
  21. Ningning Wang, Ciro Semprebon, Haihu Liu, Chuhua Zhang, Halim Kusumaatmaja, 2020, “Modelling double emulsion formation in planar flow-focusing microchannels”, Journal of Fluid Mechanics, 895:A22.
  22. Lei Wu, Qi Li, Haihu Liu, Wim Ubachs, 2020, "Extraction of the translational Eucken factor from light scattering by molecular gas", Journal of Fluid Mechanics, 901:A23.
  23. Xitong Zhang, Haihu Liu*, Jinggang Zhang, 2020, "A new capillary force model implemented in lattice Boltzmann method for gas–liquid–solid three-phase flows", Physics of Fluids, 32(10):103301.
  24. Qingqing Gu, Lianhua Zhu, Yonghao Zhang, Haihu Liu*, 2019, “Pore-scale study of counter-current imbibition in strongly water-wet fractured porous media using lattice Boltzmann method”, Physics of Fluids, 31(8):086602.
  25. Jinggang Zhang, Haihu Liu*, Yan Ba, 2019, “Numerical Study of Droplet Dynamics on a Solid Surface withInsoluble Surfactants”, Langmuir, 35: 7858-7870.
  26. Hong Liang, Haihu Liu, Zhenhua Chai, Baochang Shi, 2019, “Lattice Boltzmann method for contact-line motion of binary fluids with high density ratio”,  Physical Review E, 99: 063306.
  27. Yutong Cui, Ningning Wang, Haihu Liu*, 2019, “Numerical study of droplet dynamics in a steady electric field using a hybrid lattice Boltzmann and finite volume method”, Physics of Fluids, 31: 022105. Editor’s pick论文)
  28. Yuan Yu, Dong Liang, Haihu Liu*, 2019, “Lattice Boltzmann simulation of immiscible three-phase flows with contact-line dynamics”, Physical Review E, 99: 013308.
  29. Wei Su, Peng Wang, Haihu Liu, Lei Wu, 2019, “Accurate and efficient computation of the Boltzmann equation for Couette flow: influence of intermolecular potentials on Knudsen layer function and viscous slip coefficient”, Journal of Computational Physics, 378:573-590.
  30. Yuan Yu, Haihu Liu*, Dong Liang, Yonghao Zhang, 2019, “A versatile lattice Boltzmann model for immiscible ternary fluid flows”, Physics of Fluids, 31:012108.
  31. Meng Xu, Haihu Liu*, 2018, “Prediction of immiscible two-phase flow properties in a two-dimensional Berea sandstone using the pore-scale lattice Boltzmann simulation”, The European Physical Journal E, 41(10):124.
  32. Yan Ba, Ningning Wang, Haihu Liu*, Qiang Li, Guoqiang He, 2018, “Regularized lattice Boltzmann model for immiscible two-phase flows with power-law rheology”, Physical Review E, 97 (3):033307.
  33. Yuan Yu, Haihu Liu*, Yonghao Zhang, Dong Liang, 2018, “Color-gradient lattice Boltzmann modeling of immiscible two-phase flows on partially wetting surface”, Proceedings of the Institution of Mechanical Engineers - Part C: Journal of Mechanical Engineering Science, 232(3):416-430.
  34. Fang-Bao Tian, Yong Wang, Haihu Liu, Yonghao Zhang, 2018, "The lattice Boltzmann method and its applications in complex flows and fluid–structure interactions", Proceedings of the Institution of Mechanical Engineers - Part C: Journal of Mechanical Engineering Science, 232(3):403-404.
  35. Qingfeng Xia, Haihu Liu*, 2018, “Multi-axis dynamic displacement measurement based on a strain shunt structure”, Sensors and Actuators A: Physical, 272:62-74.
  36. Haihu Liu, Yan Ba, Lei Wu, Zhen Li, Guang Xi, Yonghao Zhang, 2018, “A hybrid lattice Boltzmann and finite difference method for droplet dynamics with insoluble surfactants”, Journal of Fluid Mechanics, 837:381-412.
  37. Qingqing Gu, Haihu Liu, Yonghao Zhang, 2018, “Lattice Boltzmann Simulation of Immiscible Two-Phase Displacement in Two-Dimensional Berea Sandstone”, Applied Sciences, 8(9):1497.
  38. Zhiyuan Xu, Haihu Liu*, Albert J Valocchi, 2017, “Lattice Boltzmann Simulation of Immiscible Two-Phase Flow with Capillary Valve Effect in Porous Media”, Water Resources Research, 53(5):3770-3790.
  39. Ningning Wang, Haihu Liu*, Chuhua Zhang, 2017, “Deformation and Breakup of a Confined Droplet in Shear Flows with Power-Law Rheology”, Journal of Rheology, 61(4):741-758.
  40. Haihu Liu, Yonghao Zhang, 2017, “Lattice Boltzmann Simulation of the Trapping of a Microdroplet in a Well of Surface Energy”, Computers & Fluids, 155:68-75.
  41. Youneng Tang, Haihu Liu*, 2017, “Modeling Multidimensional and Multispecies Biofilms in Porous Media”, Biotechnology and Bioengineering, 14(8):1679-1687.
  42. Lei Wu, Jun Zhang, Haihu Liu, Yonghao Zhang, Jason M. Reese, 2017, “A Fast Iterative Scheme for the Linearized Boltzmann Equation”, Journal of Computational Physics, 338:431-451. 
  43. Wei Su, Haihu Liu, Yonghao Zhang, Lei Wu, 2017, “Rarefaction cloaking: Influence of the fractal rough surface in gas slider bearings”, Physics of Fluids, 29:102003.
  44. Nikolaos Ioannou, Haihu Liu, Mónica S. N. Oliveira, Yonghao Zhang, 2017, “Droplet Dynamics of Newtonian and Inelastic Non-Newtonian Fluids in Confinement”, Micromachines, 8(2):57.
  45. Wei Su, Scott Lindsay, Haihu Liu, Lei Wu, 2017, “Comparative study of the discrete velocity and lattice Boltzmann methods for rarefied gas flows through irregular channels”, Physical Review E, 96:023309.
  46. Haihu Liu, Lei Wu, Yan Ba, Guang Xi, 2017, “A lattice Boltzmann method for axisymmetric thermocapillary flows”, International Journal of Heat and Mass Transfer, 104:337–350. ESI高被引论文)
  47. Haihu Liu, Lei Wu, Yan Ba, Guang Xi, Yonghao Zhang, 2016, "A lattice Boltzmann method for axisymmetric multicomponent flows with high viscosity ratio", Journal of Computational Physics, 327:873-893.
  48. Yan Ba, Haihu Liu, Qing Li, Qinjun Kang, Jinju Sun, 2016, “Multiple-relaxation-time color-gradient lattice Boltzmann model for simulating two-phase flows with high density ratio”, Physical Review E, 94, 023310.
  49. Lei Wu, Haihu Liu, Jason M Reese, Yonghao Zhang, 2016, “Non-equilibrium dynamics of dense gas under tight confinement”, Journal of Fluid Mechanics, 794:252–266.
  50. Haihu Liu, Qinjun Kang, Christopher R. Leonardi, Sebastian Schmieschek, Ariel Narvaez, Bruce D. Jones, John R. Williams, Albert J. Valocchi, Jens Harting, 2016, “Multiphase Lattice Boltzmann Simulations for Porous Media Applications”, Computational Geosciences, 20(4):777–805. ESI高被引论文)
  51. Y.W. Liu, R.J. Wu, P. Yang, T.G. Wang, H.H. Liu, L.H. Wang, “Parameter study of the injection configuration in a zero boil-off hydrogen storage tank using orthogonal test design”, Applied Thermal Engineering, 109:283–294.
  52. M. Oostrom, Y. Mehmani, P. Romero-Gomez, Y. Tang, H. Liu, H. Yoon, Q. Kang, V. Joekar-Niasar, M.T. Balhoff, T. Dewers, G.D. Tartakovsky, E.A. Leist, N.J. Hess, W.A. Perkins, C.L. Rakowski, M.C. Richmond, J.A. Serkowski, C.J. Werth, A.J. Valocchi, T.W. Wietsma, C. Zhang, 2016, “Pore-Scale and Continuum Simulations of Solute Transport Micromodel Benchmark Experiments”, Computational Geosciences, 20(4): 857–879. ESI高被引论文)
  53. Ningning Wang, Haihu Liu, Chuhua Zhang, 2016, “Three-dimensional phase-field lattice Boltzmann model for incompressible multiphase flows”, Journal of Computational Science, 17: 340-356.  
  54. N. Ioannoua, H. Liu, Y.H. Zhang, 2016, “Droplet dynamics in confinement”, Journal of Computational Science, 17:463-474.
  55. Yan Ba, Qinjun Kang, Haihu Liu, Jinju Sun, Chao Wang, 2016, “Three-dimensional lattice Boltzmann simulations of microdroplets including contact angle hysteresis on topologically structured surfaces”, Journal of Computational Science, 17: 418-430.
  56. Lei Wu, Haihu Liu, Yonghao Zhang, Jason Reese, 2015, “Influence of Intermolecular Potentials on Rarefied Gas Flows: Fast Spectral Solutions of the Boltzmann Equation”, Physics of Fluids, 27, 082002.
  57. Haihu Liu, Yaping Ju, Ningning Wang, Guang Xi, 2015, “Lattice Boltzmann modeling of contact angle and its hysteresis in two-phase flow with large viscosity difference”, Physical Review E, 92, 033306.   
  58. Haihu Liu, Yonghao Zhang, 2015, “Modeling Thermocapillary Migration of a Microfluidic Droplet on a Solid Surface”, Journal of Computational Physics, 280:37–53.
  59. Haihu Liu, Yonghao Zhang, Albert J. Valocchi, 2015, “Lattice Boltzmann Simulation of Immiscible Fluid Displacement in Porous Media: Homogeneous Versus Heterogeneous Pore Network”, Physics of Fluids, 27(5):052103.
  60. Yan Ba, Haihu Liu, Jinju Sun, Rongye Zheng, 2015, “Three Dimensional Simulations of Droplet Formation in Symmetric and Asymmetric T-Junctions Using the Color-Gradient Lattice Boltzmann Model”, International Journal of Heat and Mass Transfer, 90:931-947.
  61. Lei Zhang, Qinjun Kang, Jun Yao, Ying Gao, Zhixue Sun, Haihu Liu, Albert J. Valocchi, 2015, “Pore Scale Simulation of Liquid and Gas Two-Phase Flow Based on Digital Core Technology”, Science China Technological Sciences, 58(8):1375-1384.
  62. Jonathan Li, Haihu Liu*, Nikolaos Ioannou, Yonghao Zhang, Jason M. Reese, 2015, “Lattice Boltzmann Simulations of Thermocapillary Motion of Droplets in Microfluidic Channels”, Communications in Computational Physics, 17(5):1113-1126.
  63. Haihu Liu, Albert J. Valocchi, Yonghao Zhang, Qinjun Kang, 2014, “Lattice Boltzmann Phase Field Modeling Thermocapillary Flows in a Confined Microchannel”, Journal of Computational Physics, 256:334-356.
  64. Haihu Liu, Albert J. Valocchi, Charles J. Werth, Qinjun Kang, Mart Oostrom, 2014, “Pore-Scale Simulation of Liquid CO2 Displacement of Water Using a Two-Phase Lattice Boltzmann Model”, Advances in Water Resources, 73:144-158.
  65. Rongye Zheng, Haihu Liu, Jinju Sun, Yan Ba, 2014, “Droplet Hysteresis Investigation on Non-Wetting Striped Textured Surfaces: A Lattice Boltzmann Study”, Physica A: Statistical Mechanics and its Applications, 411:53-62.
  66. Haihu Liu, Albert J. Valocchi, Qinjun Kang, Charles J. Werth, 2013, “Pore-Scale Simulations of Gas Displacing Liquid in a Homogeneous Pore Network Using the Lattice Boltzmann Method”, Transport in Porous Media, 99:555-580.
  67. Youneng Tang, Albert J. Valocchi, Charles J. Werth, Haihu Liu*, 2013, “An Improved Pore-Scale Biofilm Model and Comparison with a Microfluidic Flow Cell Experiment”, Water Resources Research, 49(2):8370-8382.
  68. Yan Ba, Haihu Liu, Jinju Sun, Rongye Zheng, 2013, “A Color-Gradient Lattice Boltzmann Model for Simulating Droplet Motion with Contact Angle Hysteresis”, Physical Review E, 88:043306.
  69. Rongye Zheng, Jinju Sun, Haihu Liu, 2013, “A Modeling Approach to Droplet Contact-line Motion Dynamics in High-density-ratio Two-phase Flow”, Computers & Fluids, 73:175-186.
  70. Haihu Liu, Albert J. Valocchi, Yonghao Zhang, Qinjun Kang, 2013, “A Phase-Field-Based Lattice-Boltzmann Finite-Difference Model for Simulating Thermocapillary Flows”, Physical Review E, 87:013010.
  71. Haihu Liu, Albert J. Valocchi, Qinjun Kang, 2012, “Three-Dimensional Lattice Boltzmann Model for Immiscible Two-Phase Flow Simulations”, Physical Review E, 85:046309.
  72. Haihu Liu, Yonghao Zhang, Albert J. Valocchi, 2012, “Modeling and Simulation of Thermocapillary Flows Using Lattice Boltzmann Method”, Journal of Computational Physics, 231(12):4433-4453.
  73. Haihu Liu, Yonghao Zhang, 2011, “Droplet Formation in Microfluidic Cross-junctions”, Physics of Fluids, 23(8):082101. (POF期刊2012年被引次数Top 20)
  74. Haihu Liu, Yonghao Zhang, 2011, “Lattice Boltzmann Simulation of Droplet Generation in a Microfluidic Cross-junction”, Communications in Computational Physics, 9(5):1235-1256.
  75. Haihu Liu, Yonghao Zhang, 2010, “Phase-field Modeling Droplet Dynamics with Soluble Surfactants”, Journal of Computational Physics, 229(24):9166-9187.
  76. Haihu Liu, Yonghao Zhang, 2009, “Droplet Formation in a T-shaped Microfluidic Junction”, Journal of Applied Physics, 106:034906.
  77. Haihu Liu, Yonghao Zhang, 2009, “Lattice Boltzmann Simulation of Droplet Behaviour in Microfluidic Devices”, La Houille Blanche- International Water Journal, 6:84-92.

 

中文期刊论文

 

  1. 崔于桐,王宁宁,刘海湖,2017,“电场作用下微液滴变形和破裂的数值研究”,工程热物理学报,387):1564-1570.
  2. 王宁宁,刘海湖*,张楚华,2016,“液桥重开过程的两相格子Boltzmann模型及计算”, 西安交通大学学报,509):55-60.
  3. 王宁宁,刘海湖,张楚华,2016,“基于格子Boltzmann方法的Rayleigh-Taylor两相不稳定流动研究”,工程热物理学报,371):89-94.
  4. 刘双兵,刘海湖*2011,“亚网格尺度稳定化有限元求解不可压黏性流动”,力学学报,436):1083-1090.
  5. 高丽敏,刘海湖,刘波,陈云永,2008,“多级轴流压气机全三维流动特性的数值研究”,西北工业大学学报,261):1-5.
  6. 刘海湖,苏剑,高丽敏,李开泰,王尚锦,2007,“算子分裂法求解旋转坐标系下不可压黏性流动”,西安交通大学学报,417):833-837.
  7. 刘海湖,李开泰,苏剑, 王尚锦,2006,“采用算子分裂法求解不可压黏性流动”,西安交通大学学报,4012):1470-1472.
  8. 高丽敏,刘海湖,王尚锦,2006,“离心压缩机直纹面叶轮的网格生成方法”,应用力学学报,233):450-453.

著作

Yonghao Zhang, Haihu Liu, “Physics of Multiphase Microflows and Microdroplets”, In: Microdroplet Technology: Principles and Emerging Applications in Biology and Chemistry, 2012, 1-21(Springer).