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郭照立
访问教授
工学博士,二级教授,博士生导师,国家杰出青年基金获得者,长江学者特聘教授。中国工程热物理学会理事,《Scientific Report》、《Advances in Applied Mathematics and Mechanics》、《Science Bulletin》、《计算物理》编委,International Conference for Mesoscopic Methods in Engineering and Science科学委员会委员,Asian Symposium on Computational Heat Transfer and Fluid Flow国际咨询委员会委员,中国自然科学基金委员会、香港研究资助局(RGC)、英国工程和自然科学研究资助局(EPSRC)、欧盟研究资助局(ERC)项目评审专家。长期从事复杂流动与传热传质的基础理论研究和数值模拟研究,在流体动理学理论与模型、介观计算方法(格子Boltzmann方法、气体动理学格式)、跨尺度多相反应流、温室气体地质封存与利用中的渗流机理等方面,取得了重要研究进展。出版著作3本,发表SCI论文130余篇,SCI引用3200余次(他引2900+),SCI-h指数25(Google Scholar引用5800余次,h指数33),Elsevier中国高被引学者(2014、2015)。

2000.06-2003.05 华中科技大学煤燃烧国家重点实验室博士后

2003.09-2005.09 香港科技大学机械工程系访问学者

2005年至今工作于华中科技大学


2000.6年 华中科技大学  理学硕士学位

2000.6年 华中科技大学  工学博士学位

(1)介观物理模型和跨尺度的数值方法(Lattice Boltzmann方法、Gas-Kinetic Scheme方法、discrete unified gas kinetic scheme方法等); (2)跨尺度气体流动与固体传热、声子输运、稀薄/高超空气动力学;(3)多相多组分渗流微观机理;(4)多孔介质流动数值模拟(如地下水渗流,油藏工程);(5)以及其他包含溶解沉积等化学反应的流动模拟。

主要荣誉:

作为主要成员获得国家自然科学二等奖(排名第二)、教育部提名国家自然科学一等奖(排名第三)、湖北省自然科学一等奖(排名第二)。

学术论著:

在国内外权威学术刊物和会议上发表SCI论文110余篇,SCI引用2400余次,SCI H指数24;合著专著3部。


部分论著:

<1> 著作

1. 郭照立、郑楚光等,流体动力学的格子Boltzmann方法,湖北科学技术出版社,2002.

2. 郭照立、郑楚光,格子Boltzmann方法的原理及应用,科学出版社,2009.

3.  Zhaoli Guo, Chang Shu, Lattice Boltzmann Method and its Applications in Engineering, World Scientific Publisher, 2013.

<2> 期刊论文

代表论文:

1. Z.L. Guo, Well-balanced lattice Boltzmann model for two-phase systems, Phys. Fluids, 33: 031709
(2021).

2. Z.L. Guo, K. Xu, and R.J. Wang, Discrete unifified gas kinetic scheme for all Knudsen number flflows: Low-speed isothermal case, Phys. Rev. E, 88: 033305 (2013). 

3. Z.L. Guo, T.S. Zhao, Y. Shi, Simple kinetic model for flfluid flflows in the nanometer scale, Phys. Rev. E, 71: 035301 (2005).

4. Z.L. Guo, C.G. Zheng, B.C. Shi, Discrete lattice effffects on the forcing term in the lattice Boltzmann method, Phys. Rev. E, 65: 046308 (2002).

5. Z.L. Guo, C.G. Zheng, B.C. Shi, An extrapolation method for boundary conditions in lattice Boltzmann method, Phys. Fluids, 14: 2007-2010 (2002).

其它论文:

---------- 2021: ----------

1. L. Ju, B.C. Shan, Z. Yang, Z.L. Guo, An exact non-equilibrium extrapolation scheme for pressure and velocity boundary conditions with large gradients in the lattice Boltzmann method, Comput. Fluids, 231: 105163 (2021).

2. C. Zhang, S.Z. Chen, Z.L. Guo, Heat vortices of ballistic and hydrodynamic phonon transport in two-dimensional materials, Int. J. Heat Mass Transf., 176: 121282 (2021).

3. X. Wen, L.-P. Wang, Z.L. Guo, Development of unsteady natural convection in a square cavity under large temperature difffference, Phys. Fluids., 33, 084108 (2021).

4. B.C. Shan, R.X. Wang, Z.L. Guo, P. Wang, Contribution quantifification of nanoscale gas transport in shale based on strongly inhomogeneous kinetic model,Energy, 228: 120545 (2021).

5. C. Zhang, S.Z. Chen, Z.L. Guo, L. Wu, A fast synthetic iterative scheme for the stationary phonon Boltzmann transport equation, Int. J. Heat Mass Transf., 174: 121308 (2021).

6. Y. Zhang, P. Wang, Z.L. Guo, Oscillatory square cavity flflows of binary gas mixtures, Phys. Fluids, 33: 067121 (2021).

7. B. Shan, S. Chen, Z.L. Guo, P. Wang, Pore-scale study of non-ideal gas dynamics under tight confifinement considering rarefaction, denseness and molecular interactions, J. Nat. Gas Sci. Eng., 90: 103916 (2021).

8. X. Wen, L.-P. Wang, Z.L. Guo, Designing a consistent implementation of the discrete unifified gas-kinetic scheme for the simulation of three-dimensional compressible natural convection, Phys. Fluids, 33: 046101 (2021).

9. C.H. Zhang, Z.L. Guo, H. Liang, On the formulations of interfacial force in the phase-fifield-based lattice Boltzmann method, Int. J. Numer. Meth. Fl., 93: 2225–2248, (2021).

10. L. Ju, B.C. Shan, P.Y. Liu, Z.L. Guo, Pore-scale study of miscible density-driven mixing flflow in porous media, Phys. Fluids, 33: 034113 (2021).

11. X. Wen, L.-P. Wang, Z.L. Guo, D. B. Zhakebayev, Laminar to turbulent flflow transition inside the boundary layer adjacent to isothermal wall of natural convection flflow in a cubical cavity, Int. J. Heat Mass Transf. 167: 120822 (2021).

12. Z.L. Guo, K. Xu, Progress of discrete unifified gas-kinetic scheme for multiscale flflows, Adv. Aero-dyn., 3: 6 (2021).

13. Y. Zhang, P. Wang, Z.L. Guo, Oscillatory Couette flflow of rarefified binary gas mixtures, Phys. Fluids, 33: 027102 (2021).

14. P.Y. Liu, P. Wang, L. Jv, Z.L. Guo, A coupled discrete unifified gas-kinetic scheme for convection heat transfer in porous media, Commun. Comput. Phys., 29, 265–291: (2021).


---------- 2016-2019 ----------

15. X.F. Zhou, Z.L. Guo, Discrete unifified gas kinetic scheme for steady multiscale neutron transport, J. Comput. Phys.,. 423: 109767 (2020). 

16. T. Chen, X. Wen, L.-P. Wang, Z.L. Guo, J.C. Wang, S.Y. Chen, Simulation of three-dimensional compressible decaying isotropic turbulence using a redesigned discrete unifified gas kinetic scheme, Phys. Fluids, 32: 125104 (2020).

17. C. Zhang, M. An, Z.L. Guo, S.Z. Chen, Perturbation theory of thermal rectifification, Phys. Rev. E, 102: 042106 (2020).


18. S. Chen, Z.L. Guo, K. Xu, A Well-balanced gas kinetic scheme for Navier-Stokes equations with gravitational potential, Commun. Comput. Phys., 28: 902–926, (2020).

19. X. Meng, H. Sun, Z.L. Guo, X. F. Yang, A multiscale study of density-driven flflow with dissolution in porous media, Adv. Water Resour., 142: 103640 (2020).

20. C. Zhang, Z.L. Guo, S.Z. Chen, Radial thermal rectifification in concentric silicon ring from ballistic to diffffusive regime, Int. J. Heat Mass Transf., 153: 119665 (2020).

21. M.-Y. Shang, C. Zhang, Z.L. Guo, and J.-T. L¨u, Heat vortex in hydrodynamic phonon transport of two-dimensional materials, Sci. Rep., 10: 8272 (2020).

22. B.C. Shan, P. Wang, Y.H. Zhang, Z.L. Guo, Discrete unifified gas kinetic scheme for all Knudsen number flflows. IV. Strongly inhomogeneous flfluids, Phys. Rev. E, 101: 043303 (2020).

23. F.J. Peng, K. Xiong, R.X. Wang, Y. Li, Z.L. Guo, G. Feng, Molecular insight into microbehaviors of n-decane and CO2 in mineral nanopores, Energy Fuels, 34: 2925–2935 (2020).

24. L. Jv, C.H. Zhang, Z.L. Guo, Local reactive boundary scheme for lattice Boltzmann method, Int. J. Heat Mass Transf., 150: 119314 (2020). 

25. X.L. Song, C. Zhang, X.F. Zhou, Z.L. Guo, Discrete unifified gas kinetic scheme for multiscale anisotropic radiative heat transfer, Adv. Aerodyn., 2: 1-15 (2020).

26. L.H. Zhu, Z.L. Guo, Application of discrete unifified gas kinetic scheme to thermally induced nonequilibrium flflows, Comput. Fluids, 193: 103613 (2019).

27. C.H. Zhang, Z.L. Guo, Y.B. Li, A fractional step lattice Boltzmann model for two-phase flflow with large density difffferences, Int. J. Heat Mass Transf., 138: 1128-1141 (2019)

28. C. Zhang, Z.L. Guo, Discrete unifified gas kinetic scheme for multiscale heat transfer with arbitrary temperature difffference, Int. J. Heat Mass Transf., 134: 1127-1136 (2019)

29. C.H. Zhang, Z.L. Guo, H. Liang, High-order lattice-Boltzmann model for the Cahn-Hilliard equation, Phys. Rev. E, 99: 043310 (2019).

30. J.J. Hu, Z.L. Guo, Effffect of interaction between a particle cluster and a single particle on particle motion and distribution during sedimentation: A numerical study, Phys. Fluids, 31: 033301 (2019). 

31. C. Zhang, Z.L. Guo, S.Z. Chen, An implicit kinetic scheme for multiscale heat transfer problem accounting for phonon dispersion and polarization, Int. J. Heat Mass Transf., 130: 1366-1376 (2019).

32. Y. Zhang, L.H. Zhu, P. Wang, Z.L. Guo, Discrete unifified gas kinetic scheme for flflows of binary gas mixture based on the McCormack model, Phys. Fluids, 31: 017101 (2019).

33. S. Tao, H.L. Zhang, Z.L. Guo, L.P. Wang, A combined immersed boundary and discrete unifified gas kinetic scheme for particle-flfluid flflows, J. Comput. Phys., 375: 498-518 (2018).

34. X.H. Meng, L. Wang, X.F. Yang, Z.L. Guo, Preconditioned multiple-relaxation-time lattice Boltzmann equation model for incompressible flflow in porous media, Phys. Rev. E, 98: 053309 (2018).

35. C.H. Zhang, K. Yang, Z.L. Guo, A discrete unifified gas-kinetic scheme for immiscible two-phase flflows, Int. J. Heat Mass Transf., 126: 1326-1336 (2018).

36. R.X. Wang, F.J. Peng, K.L. Song, G. Feng, Z.L. Guo, Molecular dynamics study of interfacial properties in CO2 enhanced oil recovery, Fluid Phase Equilibria, 467: 25-32 (2018).

37. S. Tao, H.L. Zhang, Z.L. Guo, L.P. Wang, Numerical investigation of dilute aerosol particle transport and deposition in oscillating multi-cylinder obstructions, Adv. Powder Tech. 29: 2003-2018 (2018).

38. Y. Zhang, L.H. Zhu, R.J. Wang, Z.L. Guo, Discrete unifified gas kinetic scheme for all Knudsen number flflows. III. Binary gas mixtures of Maxwell molecules, Phys. Rev. E, 97: 053306 (2018).

39. C. Peng, N. Geneva, Z.L. Guo, L.P. Wang, Direct numerical simulation of turbulent pipe flflow using the lattice Boltzmann method, J. Comput. Phys., 357: 16-42 (2018).

40. J.J. Hu, Z.L. Guo, Numerical study on mass transfer from a composite particle settling in a vertical channel, Int. J. Heat Mass Transf., 117: 132-142 (2018).

41. P. Wang, M.T. Ho, L. Wu, Z.L. Guo, Y.H. Zhang, A comparative study of discrete velocity methods for low-speed rarefified gas flflows, Comput. Fluids, 161: 33-46 (2018).

42. L.H. Zhu, X.F. Yang, Z.L. Guo, Thermally induced rarefified gas flflow in a three-dimensional enclosure with square cross-section, Phys. Rev. Fluids, 2: 123402 (2017).

43. C. Zhang, Z.L. Guo, S.Z. Chen, Unifified implicit kinetic scheme for steady multiscale heat transfer based on the phonon Boltzmann transport equation, Phys. Rev. E, 96: 063311 (2017).

44. C. Peng, Z.L. Guo, L.P. Wang, Lattice Boltzmann model capable of mesoscopic vorticity computation, Phys. Rev. E, 96: 053304 (2017).

45. P. Wang, Y.H. Zhang, Z.L. Guo, Numerical study of three-dimensional natural convection in a cubical cavity at high Rayleigh numbers, Int. J. Heat Mass Transf., 113: 217-228 (2017).

46. S. Tao, Z.L. Guo, Gas-solid drag coeffiffifficient for ordered arrays of monodisperse microspheres in slip flflow regime, Chem. Eng. Tech., 40: 1758–1766 (2017).

47. S. Tao, Z.L. Guo, L.P. Wang, Numerical study on the sedimentation of single and multiple slippery particles in a Newtonian flfluid, Powder Tech., 315: 126-138 (2017).

48. J. Hu, Z.L. Guo, A numerical study on the migration of a neutrally buoyant particle in a Poiseuille flflow with thermal convection, Int. J. Heat Mass Transf., 108: 2158–2168 (2017).

49. L.H. Zhu, Z.L. Guo, Numerical study of nonequilibrium gas flflow in a microchannel with a ratchet surface, Phys. Rev. E, 95: 023113 (2017).

50. J.J. Hu, S. Tao, Z.L. Guo, An effiffifficient unifified iterative scheme for moving boundaries in lattice Boltzmann method, Comput. Fluids, 144:34-43 (2017).

51. S. Tao, H.L. Zhang, Z.L. Guo, Drag correlation for micro spherical particles at fifinite Reynolds and Knudsen numbers by lattice Boltzmann simulations, J. Aeros. Sci. 103: 105-116 (2017).


52. C. Peng, N. Geneva, Z.L. Guo, L.-P. Wang, Issues associated with Galilean invariance on a moving solid boundary in the lattice Boltzmann method, Phys. Rev. E, 95: 013301 (2017).

53. S.Z. Chen, C. Zhang, L.H. Zhu, Z.L. Guo, A unifified implicit scheme for kinetic model equations. Part I. Memory reduction technique, Sci. Bulletin, 62: 119–129 (2017).

54. L.H. Zhu, P. Wang, Z.L. Guo, Performance evaluation of the general characteristics based offff-latticeBoltzmann scheme and DUGKS for low speed continuum flflows, J. Comput. Phys., 333: 227–246 (2017).

55. L.H. Zhu, S.Z. Chen, Z.L. Guo, dugksFoam: An open source OpenFOAM solver for the Boltzmann model equation, Comput. Phys. Commun., 213: 155–164 (2017).

56. Z.L. Guo, K. Xu, Discrete unifified gas kinetic scheme for multiscale heat transfer based on the phonon Boltzmann transport equation, Int. J. Heat Mass Transf., 102: 944-958 (2016).

57. P. Wang, L.-P. Wang, Z.L. Guo, Comparison of the lattice Boltzmann equation and discrete unifified gas-kinetic scheme methods for direct numerical simulation of decaying turbulent flflows, Phys. Rev. E, 94: 043304 (2016).

58. L. Wang, Z.M. Xu, Z.L. Guo, Lattice Boltzmann simulation of separation phenomenon in a binary gaseous flflow through a microchannel, J. Appl. Phys., 120: 134306 (2016).

59. X.H. Meng, Z.L. Guo, Localized lattice Boltzmann equation model for simulating miscible viscous displacement in porous media, Int. J. Heat Mass Transf., 100: 767-778 (2016).

60. S.Z. Chen, Z.L. Guo, K. Xu, Simplifification of the unifified gas kinetic scheme, Phys. Rev. E, 94: 023313 (2016).

61. P. Wang, Z.L. Guo, A semi-implicit gas-kinetic scheme for smooth flflows, Comput. Phys. Commun., 205: 22-31 (2016).

62. S. Tao, J.J. Hu, Z.L. Guo, An investigation on momentum exchange methods and refifilling algorithms for lattice Boltzmann simulation of particulate flflows, Comput. Fluids, 133: 1-14 (2016).

63. C. Peng, H. Min, Z.L. Guo, L.-P. Wang, A hydrodynamically-consistent MRT lattice Boltzmann model on a 2D rectangular grid, J. Comput. Phys., 326: 893–912 (2016).

64. K. Yang, Z.L. Guo, Lattice Boltzmann method for binary flfluids based on mass-conserving quasi incompressible phase-fifield theory, Phys. Rev. E, 93: 043303 (2016).

65. L.-P. Wang, C. Peng, Z.L. Guo, Z.S. Yu, Flow modulation by fifinite-size neutrally buoyant particles in a turbulent channel flflow, J. Fluids Eng., 138: 041306 (2016).

66. J.J. Ren, P. Guo, Z.L. Guo Rectangular lattice Boltzmann equation for gaseous microscale flflow, Adv. Appl. Math. Mech., 8: 306-330 (2016).

67. L.H. Zhu, Z.L. Guo, K. Xu, Discrete unifified gas kinetic scheme on unstructured meshes, Comput. Fluids, 127: 211-225 (2016). 

68. L. Wang, J.C. Mi, Z.L. Guo, A modifified lattice Bhatnagar-Gross-Krook model for convection heat transfer in porous media, Int. J. Heat Mass Transf., 94: 269-291 (2016).

69. G.J. Liu, Z.L. Guo, B.C. Shi, A coupled lattice Boltzmann model for flfluid flflow and diffffusion in a porous medium, Acta Phys. Sinica, 65: 014702 (2016).

70. K. Yang, Z.L. Guo, Lattice Boltzmann study of wettability alteration in the displacement of nanoparticle-fifilled binary flfluids, Comput. Fluids, 124: 157-169 (2016).

71. L.-P. Wang, C. Peng, Z.L. Guo, Z.S. Yu, Lattice Boltzmann simulation of particle-laden turbulent channel flflow, Comput. Fluids, 124: 226-236 (2016).

---------- 2011-2015 ----------

72. X.H. Meng, Z.L. Guo, Multiple-relaxation-time lattice Boltzmann model for incompressible miscible flflow with large viscosity ratio and high P´eclet number, Phys. Rev. E, 92: 043305 (2015).

73. P. Wang, S. Tao, Z.L. Guo, A coupled discrete unifified gas-kinetic scheme for Boussinesq flflows, Comput. Fluids, 120:70–81 (2015).

74. S. Tao and Z.L. Guo, Boundary condition for lattice Boltzmann modeling of microscale gas flflows with curved walls in the slip regime. Phys. Rev. E, 91: 043305 (2015).

75. L. Wang, J.C. Mi, X.H. Meng, and Z.L. Guo, A Localized Mass-Conserving Lattice Boltzmann Approach for Non-Newtonian Fluid Flows Commun. Comput. Phys., 17: 908-924 (2015).

76. G.J. Liu and Z.L. Guo, Pore-Scale Study of the Non-Linear Mixing of Fluids with Viscous Fingering in Anisotropic Porous Media Commun. Comput. Phys., 17: 1019-1036 (2015).

77. Z.L. Guo, R. Wang, and K. Xu, Discrete unifified gas kinetic scheme for all Knudsen number flflows. II. Thermal compressible case, Phys. Rev. E, 91: 033313 (2015).

78. P. Wang, L. Zhu, Z.L. Guo, and K. Xu, A comparative study of LBE and DUGKS methods for nearly incompressible flflows, Commun. Comput. Phys., 17: 657-681 (2015). 

79. K. Yang and Z.L. Guo, Multiple-relaxation-time lattice Boltzmann model for binary mixtures of nonideal flfluids based on the Enskog kinetic theory, Sci. Bullet., 60: 634-647 (2015).

80. L. Wang, L. P. Wang, Z.L. Guo, J. Mi, Volume-averaged macroscopic equation for flfluid flflow in moving porous media, Int. J. Heat Mass Transf., 82: 357-368 (2015).

81. Q. Lou and Z.L. Guo, Interface-capturing lattice Boltzmann equation model for two-phase flflows, Phys. Rev. E, 91: 013302 (2015).

82. J. Ren, P. Guo, Z.L. Guo, and Z. Wang, A lattice Boltzmann model for fifimulating gas flflow in kerogen pores, Trans. Porous Media, 106: 285-301 (2015).

83. S. Tao, L. Wang, Z.L. Guo, Lattice Boltzmann modeling of microscale oscillating Couette flflow, Acta Phys. Sinica, 63: 214703 (2014).

84. L. Wang, Z.L. Guo, and J. C. Mi, Drafting, kissing and tumbling process of two particles with difffferent sizes, Comput. Fluids, 96: 20-34 (2014).

85. Y. Xiong and Z.L. Guo, Effffects of density and force discretizations on spurious velocities in lattice Boltzmann equation for two-phase flflows, J. Phys. A, 47: 195502 (2014).

86. L. Zheng, T. Lee, Z.L. Guo, and D. Rumschitzki, Shrinkage of bubbles and drops in the lattice Boltzmann equation method for nonideal gases, Phys. Rev. E, 89: 033302 (2014).

87. Z.L. Guo, J. Qin, and C.G. Zheng, Generalized second-order slip boundary condition for nonequilibrium gas flflows, Phys. Rev. E, 89: 013021 (2014).

88. Z.M. Xu and Z.L. Guo, Pressure distribution of the Gaseous flflow in microchannel: a Lattice Boltzmann study, Commun. Comput. Phys., 14: 1058-1072 (2013).

89. Q. Lou, Z.L. Guo, and B.C. Shi, Evaluation of outflflow boundary conditions for two-phase lattice Boltzmann equation, Phys. Rev. E, 87: 063301 (2013).

90. L. Wang, Z.L. Guo, B.C. Shi, and C.G. Zheng, Evaluation of three lattice Boltzmann models for particulate flflows. Commun. Comput. Phys., 13: 1151-1172 (2013).

91. W. Mao, AAA, L. Wang, Lattice Boltzmann simulation of the sedimentation of particles with thermal convection, Acta Phys. Sinica, 62: 084703 (2013).

92. X.L. Liu, Z.L. Guo, A lattice Boltzmann study of gas flflows in a long micro-channel. Comput. Math. Appl., 65: 186-193 (2013).

93. G. Liu and Z.L. Guo, Effffects of Prandtl number on mixing process in miscible Rayleigh-Taylor instability. Int. J. Numer. Meth. Heat Fluid Flow, 23: 176-188 (2013)

94. Q. Lou, Z.L. Guo, and B.C. Shi, Effffects of force discretization on mass conservation in lattice Boltzmann equation for two-phase flflows. EPL, 99: 64005 (2012).

95. L. Zheng, Z.L. Guo, and B.C. Shi, Microscale boundary conditions of the lattice Boltzmann equation method for simulating microtube flflows. Phys. Rev. E, 856: 016712 (2012).

96. Z.L. Guo, C.G. Zheng, B.C. Shi, Force imbalance in lattice-Boltzmann equation for two-phase flflows, Phys. Rev. E 83: 036707 (2011) 

97. K. Xu and Z.L. Guo, Multiple temperature gas dynamic equations for non-equilibrium flflows. J. Comput. Math., 29: 639-660 (2011).

98. Z.L. Guo, C.G. Zheng, B.C. Shi, Checkerboard effffects on spurious currents in lattice Boltzmann equation for two-phase flflows. Phil. Trans. Royal Soc. A, 369: 2283-2291 (2011).

99. Q. Lou, Z.L. Guo, and C.G. Zheng, Some fundamental properties of lattice Boltzmann equation for two phase flflows. CMES-Comput. Mod. Eng. Sci., 76: 175-188 (2011).

100. Z.L. Guo, B.C. Shi, C.G. Zheng, Velocity inversion of micro cylindrical Couette flflow: A lattice Boltzmann study. Comput. Math. Appl., 61: 3519-3527 (2011).

---------- 2006-2010 ----------


101. Lin Zheng, Z.L. Guo, B.C. Shi, C.G. Zheng, Lattice Boltzmann method for thermocapillary flflows, Adv. Appl. Math. Mech., 2: 677–684 (2010).

102. Liang Wang, Z.L. Guo, C.G. Zheng, Multi-relaxation-time lattice Boltzmann model for axisymmetric flflows. Comput. Fluids, 39: 1542-1548 (2010).

103. Lin Zheng, Z.L. Guo, B.C. Shi, C.G. Zheng, Kinetic theory based lattice Boltzmann equation with viscous dissipation and pressure work for axisymmetric thermal flflows. J. Comput. Phys., 229: 5843-5856 (2010) .

104. Lin Zheng, Baochang Shi, Z.L. Guo, C.G. Zheng, Lattice Boltzmann equation for axisymmetric thermal flflows. Comput. Fluids, 39: 945-952 (2010) .

105. Lin Zheng, Z.L. Guo, B.C. Shi, C.G. Zheng, Finite-difffference-based multiple-relaxation-times lattice Boltzmann model for binary mixtures. Phys. Rev. E, 81: 016706 (2010).

106. Z.L. Guo, Kun Xu, Numerical validation of Brenners hydrodynamic model by force driven Poiseuille flflow. Adv. Appl. Math. Mech., 1: 391-401 (2009).

107. Z.L. Guo, H.F. Han, B.C. Shi, C.G. Zheng, Theory of the lattice Boltzmann equation: Lattice Boltzmann model for axisymmetric flflows. Phys. Rev. E, 79: 046708, (2009).

108. Z.L. Guo, P. Asinari, C.G. Zheng, Lattice Boltzmann equation for microscale gas flflows of binary mixtures. Phys. Rev. E, 79: 026702 (2009).

109. K. Xu, Z.L. Guo, Generalized gas dynamic equations with multiple translational temperatures. Mod. Phys. Lett. B, 23: 237-240 (2009).

110. B.C. Shi, Z.L. Guo, Lattice Boltzmann model for nonlinear convection-diffffusion equations. Phys. Rev. E, 79: 016701 (2009). 

111. Z.L. Guo, C.G. Zheng, B.C. Shi, Incompressible lattice Boltzmann model for porous flflows with large pressure gradient. Prog. Comput. Fluid Dyn., 9: 225-230 (2009).

112. Lin Zheng, B.C. Shi, Z.L. Guo, Multiple-relaxation-time model for the correct thermohydrodynamic equations. Phys. Rev. E, 78: 026705 (2008).

113. Lin Zheng, Z.L. Guo, B.C. Shi, Discrete effffects on thermal boundary conditions for the thermal lattice Boltzmann method in simulating microscale gas flflows. EPL, 82: 44002 (2008).

114. Z.L. Guo, Hongwei Liu, Li-Shi Luo, K. Xu, A comparative study of the LBE and GKS methods for 2D near incompressible laminar flflows. J. Comput. Phys., 227: 4955-4976 (2008).

115. Z.L. Guo, C.G. Zheng, B.C. Shi, Lattice Boltzmann equation with multiple effffective relaxation times for gaseous microscale flflow. Phys. Rev. E, 77: 036707, (2008).

116. Z.L. Guo, C.G. Zheng, Analysis of lattice Boltzmann equation for microscale gas flflows: Relaxation times, boundary conditions and the Knudsen layer. Int. J. Comput. Fluid Dyn., 22: 465-473 (2008).

117. Z.L. Guo, B.C. Shi, C.G. Zheng, An extended Navier-Stokes formulation for gas flflows in the Knudsen layer near a wall, Europhy. Lett., 80: 24001 (2007).

118. Z.L. Guo, C.G. Zheng. B.C. Shi, T.S. Zhao, Thermal lattice Boltzmann equation for low Mach number flflows: decoupling model, Phys. Rev. E, 75: 036704 (2007). 

119. Z.L. Guo, B.C. Shi, T.S. Zhao, C.G. Zheng, Discrete effffects on boundary conditions for the lattice Boltzmann equation in simulating microscale gas flflows, Phys. Rev. E, 76: 056704 (2007).

120. Z.L. Guo, T.S. Zhao, Y. Shi, Generalized hydrodynamic model for flfluid flflows: from nanoscale to macroscale, Phys. Fluids, 18: 067107 (2006). 

121. Z.L. Guo, T.S. Zhao, C. Xu, Y. Shi, Simulation of flfluid flflows in the nanometer: kinetic approach and molecular dynamic simulation, Int. J. Comput. Fluid Dyn., 20: 361–367 (2006).

122. Z.L. Guo, T.S. Zhao, Y. Shi, Physical symmetry, spatial accuracy, and relaxation time of the lattice Boltzmann equation for microgas flflows, J. Appl. Phys., 99: 074903 (2006).

---------- 2005 and before ----------

123. Z.L. Guo, T.S. Zhao, Y. Shi, Temperature dependence of the velocity boundary condition for nanoscale flfluid flflows, Phys. Rev. E, 72: 036301 (2005).

124. Z.L. Guo, T.S. Zhao, Y. Shi, A Lattice Boltzmann algorithm for electro-osmotic flflow in microflfluid devices, J. Chem. Phys., 122: 144907 (2005).

125. Z.L. Guo, T.S. Zhao, A lattice Boltzmann model for convection heat transfer in porous media, Num. Heat Trans. B, 47: 157–177 (2005). 

126. Z.L. Guo, T.S. Zhao, Finite-difffference-based lattice Boltzmann model for dense binary mixtures, Phys. Rev. E, 71: 026701 (2005).

127. Z.L. Guo, T.S. Zhao, Lattice Boltzmann simulation of natural convection with temperature-dependent viscosity in a porous cavity, Prog. Comput. Fluid Dyn., 5: 110–117 (2005).

128. Z.L. Guo, T.S. Zhao, Y. Shi, Preconditioned lattice-Boltzmann method for steady flflows, Phys. Rev. E, 70: 066706 (2004).

129. Z.L. Guo, T.S. Zhao, Discrete velocity and lattice Boltzmann models for binary mixtures of nonideal flfluids, Phys. Rev. E, 68: 035302 (2003). Parallel simulation of flfluid flflows and its visualization

130. Z.L. Guo, T.S. Zhao, Explicit fifinite-difffference lattice Boltzmann method for curvilinear coordinates, Phys. Rev. E, 67: 066709 (2003).

131. Z.L. Guo, C.G. Zheng, B.C. Shi, Domain-decomposition technique in lattice Boltzmann method, Int. Mod. Phys. B, 17: 129–133 (2003). 

132. Z.L. Guo, T.S. Zhao, Lattice Boltzmann model for incompressible flflows through porous media, Phys. Rev. E, 66: 036304 (2002).

133. Z.L. Guo, B.C. Shi, C.G. Zheng, A coupled lattice BGK model for the Boussinesq equations, Int. J. Numer. Meth. Fl., 39: 325–342 (2002).

134. Z.L. Guo, C.G. Zheng, B.C. Shi, Non-equilibrium extrapolation method for velocity and pressure boundary conditions in the lattice Boltzmann method, Chinese Phys., 11: 366–374 (2002).

135. Z.L. Guo, C.G. Zheng, T.S. Zhao , A lattice BGK scheme with general propagation, J. Sci. Comput., 16: 569–585 (2001).

136. Z.L. Guo, B.C. Shi, N.C. Wang, Two new algorithms based on product system for discrete cosine transform, Signal process., 81: 1899–1908 (2001).

137. Z.L. Guo, B.C. Shi, N.C. Wang, Lattice BGK model for incompressible Navier-Stokes equation, J. Comput. Phys., 165: 288–306 (2000).

138. Z.L. Guo, B.C. Shi, N.C. Wang, Fully Lagrangian and lattice Boltzmann methods for the advection diffffusion equation, J. Sci. Comput., 14: 291-300 (1999).