Lattice Boltzmann modeling and simulation of compressible flows AG Xu, GC Zhang, YB Gan, F Chen, XJ Yu Frontiers of Physics 7 (5), 582-600, 2012 | 131 | 2012 |

Two-dimensional lattice Boltzmann model for compressible flows with high Mach number Y Gan, A Xu, G Zhang, X Yu, Y Li Physica A: Statistical Mechanics and its Applications 387 (8), 1721-1732, 2008 | 101 | 2008 |

Multiple-relaxation-time lattice Boltzmann approach to compressible flows with flexible specific-heat ratio and Prandtl number F Chen, A Xu, G Zhang, Y Li, S Succi EPL (Europhysics Letters) 90 (5), 54003, 2010 | 93 | 2010 |

Lattice Boltzmann study on Kelvin-Helmholtz instability: Roles of velocity and density gradients Y Gan, A Xu, G Zhang, Y Li Physical Review E 83 (5), 056704, 2011 | 86 | 2011 |

Lattice Boltzmann model for combustion and detonation B Yan, AG Xu, GC Zhang, YJ Ying, H Li Frontiers of Physics 8 (1), 94-110, 2013 | 83 | 2013 |

Lattice BGK kinetic model for high-speed compressible flows: Hydrodynamic and nonequilibrium behaviors Y Gan, A Xu, G Zhang, Y Yang EPL (Europhysics Letters) 103 (2), 24003, 2013 | 71 | 2013 |

Phase separation in thermal systems: A lattice Boltzmann study and morphological characterization Y Gan, A Xu, G Zhang, Y Li, H Li Physical Review E 84 (4), 046715, 2011 | 67 | 2011 |

Phase separation in thermal systems: LB study and morphological characterization Y Gan, A Xu, G Zhang, Y Li arXiv preprint arXiv:1012.2277, 2010 | 67* | 2010 |

Polar-coordinate lattice Boltzmann modeling of compressible flows C Lin, A Xu, G Zhang, Y Li, S Succi Physical Review E 89 (1), 013307, 2014 | 66 | 2014 |

Lattice Boltzmann approach to high-speed compressible flows XF Pan, A Xu, G Zhang, S Jiang International Journal of Modern Physics C 18 (11), 1747-1764, 2007 | 56 | 2007 |

Three-dimensional multi-mesh material point method for solving collision problems P Xiao-Fei, X Ai-Guo, Z Guang-Cai, Z Ping, Z Jian-Shi, M Shang, Z Xiong Communications in Theoretical Physics 49 (5), 1129, 2008 | 49 | 2008 |

Multiple-relaxation-time lattice Boltzmann model for compressible fluids F Chen, A Xu, G Zhang, Y Li Physics Letters A 375 (21), 2129-2139, 2011 | 46 | 2011 |

First-principles study of surface properties of PuO< sub> 2</sub>: Effects of thickness and O-vacancy on surface stability and chemical activity B Sun, H Liu, H Song, G Zhang, H Zheng, X Zhao, P Zhang Journal of Nuclear Materials 426 (1), 139-147, 2012 | 43 | 2012 |

Lattice Boltzmann study of thermal phase separation: Effects of heat conduction, viscosity and Prandtl number Y Gan, A Xu, G Zhang, P Zhang, Y Li EPL (Europhysics Letters) 97 (4), 44002, 2012 | 43 | 2012 |

Highly efficient lattice Boltzmann model for compressible fluids: two-dimensional case C Feng, X Ai-Guo, Z Guang-Cai, G Yan-Biao, C Tao, L Ying-Jun Communications in Theoretical Physics 52 (4), 681, 2009 | 39 | 2009 |

Molecular dynamics simulations of hcp/fcc nucleation and growth in bcc iron driven by uniaxial compression BT Wang, JL Shao, GC Zhang, WD Li, P Zhang Journal of Physics: Condensed Matter 21 (49), 495702, 2009 | 35 | 2009 |

Polar coordinate lattice Boltzmann modeling of detonation phenomena C Lin, A Xu, G Zhang, Y Li arXiv preprint arXiv:1308.0653, 2013 | 31* | 2013 |

Three-dimensional lattice Boltzmann model for high-speed compressible flows C Feng, X Ai-Guo, Z Guang-Cai, L Ying-Jun Communications in Theoretical Physics 54 (6), 1121, 2010 | 31 | 2010 |

Three-Dimensional Lattice Boltzmann Model for High-Speed Compressible Flows 陈锋， 许爱国， 张广财， 李英骏 Communications in Theoretical Physics 12, 031, 2010 | 31* | 2010 |

Generalized interpolation material point approach to high melting explosive with cavities under shock XF Pan, A Xu, G Zhang, J Zhu Journal of Physics D: Applied Physics 41 (1), 015401, 2008 | 28 | 2008 |