大连理工大学

[1]         陶实，周力，宗智. 串列对转双圆柱的多块LB模拟[J]. 计算物理, 2013, 2(30): 161-168

[2]         陶实，周力，宗智，李薇. 基于分布函数预测-修正的LBM曲边边界处理新方法[J].水动力学研究与进展A辑, 2013, 6(28): 717-723

[3]         陶实，周力，宗智. 基于格子Boltzmann方法的圆柱两自由度涡激振动的研究[J].水动力学研究与进展A辑, 2013, 2(28): 167-175

华中科技大学

[4]         陶实, 王亮, 郭照立. 微尺度振荡 Couette 流的格子 Boltzmann 模拟[J]. 物理学报, 2014, 63(21): 214703-214703.  (IF: 1.083, SCI)

[5]         Tao Shi, Guo Zhaoli. Boundary condition for lattice Boltzmann modeling of microscale gas flows with curved walls in the slip regime[J]. Physical Review E, 2015, 91(4): 043305.  (IF:2.366, SCI) 代表作1，引用：28次

[6]         Tao Shi, Hu Junjie, Guo Zhaoli. An investigation on momentum exchange methods and refilling algorithms for lattice Boltzmann simulation of particulate flows[J]. Computers & Fluids, 2016, 133: 1-14.  (IF: 2.313, SCI) 代表作2，引用：25次

[7]         Tao Shi, Zhang Haolong, Guo Zhaoli. Drag correlation for micro spherical particles at finite Reynolds and Knudsen numbers by lattice Boltzmann simulations[J]. Journal of Aerosol Science, 2017, 103:105-116. (IF: 2.281, SCI)

[8]         Tao Shi, Guo Zhaoli, Lianping Wang. Numerical study on the sedimentation of single and multiple slippery particles in a Newtonian fluid[J]. Powder Technology, 2017, 315: 126- 138. (IF: 3.230, SCI)

[9]         Tao Shi, Guo Zhaoli. Gas‐Solid Drag Coefficient for Ordered Arrays of Monodisperse Microspheres in Slip Flow Regime. Chemical Engineering &Technology, 2017, 40(10): 1758-1766. (IF: 2.051, SCI)

[10]      Tao Shi, Zhang Haolong, Guo Zhaoli, Lianping Wang. Numerical investigation of dilute aerosol particle transport and deposition in oscillating multi-cylinder obstructions. Advanced Powder Technology, 2018, 29(9): 2003-2018. (IF: 2.943, SCI)

[11]      Tao Shi, Zhang Haolong, Guo Zhaoli, Lianping Wang. A combined immersed boundary and discrete unified gas kinetic scheme for particle-fluid flows. Journal of Computational Physics, 2018, 375(15): 498-518. (IF: 2.864, SCI) 代表作3，计算流体力学顶级期刊，引用1次

[12]      Wang Peng, Tao Shi, Guo Zhaoli. A coupled discrete unified gas-kinetic scheme for Boussinesq flows[J]. Computers & Fluids, 2015, 120: 70-81. (SCI)

[13]      Hu Junjie, Tao Shi, Guo Zhaoli. An efficient unified iterative scheme for moving boundaries in lattice Boltzmann method[J]. Computers & Fluids, 2017, 144: 34-43. (SCI)

[14]      张浩龙, 陶实, 郭照立. 离散统一气体动理学格式的浸入边界方法[J]. 工程热物理学报, 2016, 3(37): 539-544.

[15]      张浩龙，陶实，郭照立. 振动纤维捕集颗粒的格子Boltzmann模拟[J]. 计算物理, 2016, 3(33): 311-321.

东莞理工学院

[16]      Tao Shi, He Qing, Chen Baiman, Yang Xiaoping, Huang Simin. One-point second-order curved boundary condition for lattice Boltzmann simulation of suspended particles. Computers & Mathematics with Applications, 2018, 76(7): 1593-1607. (IF: 1.860, SCI)

[17]      Tao Shi, He Qing, Chen Baiman, Yang Xiaoping, Huang Simin. A direct force model for Galilean invariant lattice Boltzmann simulation of fluid-particle flows. International Journal of Modern Physics C, 2018, 29(03): 1850021. (IF: 1.171, SCI)

[18]      Tao Shi, Chen Baiman, Yang Xiaoping, Huang Simin. Second-order accurate immersed boundary-discrete unified gas kinetic scheme for fluid-particle flows. Computers & Fluids, 2018, 165: 54-63. (IF: 2.313, SCI)

[19]      Tao Shi, He Qing, Wang Lei, Huang Simin, Chen Baiman. A non-iterative direct-forcing immersed boundary method for thermal discrete unified gas kinetic scheme with Dirichlet boundary conditions. International Journal of Heat and Mass Transfer, 2019, 137: 476-488. (IF: 3.891, SCI)

[20]      Tao Shi, He Qing, Chen Jiechao, Chen Baiman, Yang Guang(学), & Wu Zhibin(学). (2019). A non-iterative immersed boundary-lattice Boltzmann method with boundary condition enforced for fluid-solid flows. Applied Mathematical Modelling. Applied Mathematical Modelling, 2019, 76: 362-379. (SCI)

[21]     Shasha Liu, Taotao Zhou,TaoShi*, ZhibinWu(学), Guang Yang(学). Lattice Boltzmann simulation of particle-laden flows using an improved curved boundary condition. International Journal of Modern Physics C, 2019, On line. (SCI)

[22]      Zhang Wen-Kai, Yang Minlin, Chen Jie-Chao, Tao Shi, Huang Xiangxuan, Hu Bing, Huang Si-Min, Quasi-counter flow parallel-plate membrane contactors (QCPMC) for liquid desiccant air dehumidification: Conjugate heat and mass transfer. International Journal of Thermal Sciences, 2018, On line. (SCI)

[23]      Huang Si-Min, Yang Minlin, Huang Wei-Hao, Tao Shi, Hu Bing, Qin G.F.Frank. An analytical solution of heat and mass transfer in a counter/parallel flow plate membrane module used in an absorption heat pump. International Journal of Thermal Sciences, 2018, 124: 110-121. (SCI)

[24]        Tao Shi, A Xu, Q He, B Chen, FGF Qin. A curved lattice Boltzmann boundary scheme for thermal convective flows with Neumann boundary condition. International Journal of Heat and Mass Transfer, 2020, 150: 119345.  

[25]        Tao Shi, He, Q., Chen, B., Qin, F. G., & Lin, Y. (2020). A ghost-cell discrete unified gas kinetic scheme for thermal flows with heat flux at curved interface. International Journal of Heat and Mass Transfer, 162, 120365.

[26]         Tao Shi, Wang, L., Ge, Y., & He, Q. (2021). Application of half-way approach to discrete unified gas kinetic scheme for simulating pore-scale porous media flows. Computers & Fluids, 214, 104776.

[27]  Tao, S., He, Q., Chen, B., & Qin, F. G. (2021). Distribution function correction-based immersed boundary lattice Boltzmann method for thermal particle flows. Computational Particle Mechanics, 8(3), 459-469.

[28] Tao, S., He, Q., Wang, L., Chen, B., Chen, J., & Lin, Y. (2021). Discrete unified gas kinetic scheme simulation of conjugate heat transfer problems in complex geometries by a ghost-cell interface method. Applied Mathematics and Computation, 404, 126228.

[29] He, Q., Tao, S., Yang, X., Lu, W., & He, Z. (2021). Discrete unified gas kinetic scheme simulation of microflows with complex geometries in Cartesian grid. Physics of Fluids, 33(4), 042005.

       [30] Liu, S., He, Q., Tao, S. *, Wang, W., & Luo, J. (2022). Lattice Boltzmann simulation of particles inertial migration with slippery        surface  and moderate concentration in circular tube flow. International Journal of Modern Physics C (On line).

       [31] Tao, S.*, He, Q., Yang, X., Luo, J., & Zhao, X. (2022). Numerical study on the drag and flow characteristics of porous particles at      intermediate Reynolds numbers. Mathematics and Computers in Simulation, 202,  273-294.

       [32] Tao, S.*, Wang L., He, Q., Chen, J., & Luo, J. (2022). Interface-resolved simulation of solid-liquid phase change with thermal convection using discrete unified gas kinetic scheme. Computers & Mathematics with Applications, 125,  213-221.

         [33] Tao, S., Wang, L., He, Q., Chen, J., & Luo, J. (2022). A sharp interface immersed boundary-discrete unified gas kinetic scheme for fluid-solid flows with heat transfer. International Communications in Heat and Mass Transfer, 139, 106424.

         [34] Tao, S., Wang, L., He, Q., Chen, J., & Luo, J. (2022). Lattice Boltzmann simulation of complex thermal flows via a simplified immersed boundary          method. Journal of Computational Science, 101878.

本科毕业设计：指导42人（其中8人获校优秀本科毕业论文：苏洋，苏宏孟（2019）；吴漫纯，苏明旺（2020）；黄丽娜，李裕均（2021）；杨涛，里镇富（2022））。

兼职辅导员（2017），获校优秀班主任（2018）、校优秀党员（2019）。