Google Scholar Citation Record
ResearchGate for preprints
C. Zhao, S.S. Patel, R. Balakrishnan, and T. Lee, "IMEXLBM: Portable Single-phase Lattice Boltzmann Solver based on Kokkos Library," in preparation
C. Zhao, T. Lee, and A. Carlson, "Spreading and engulfment of a viscoelastic film onto a Newtonian droplet," under review (arXiv preprint arXiv:2401.17762)
C. Zhao, S.S. Patel, and T. Lee, "A Difference-free Conservative Phase-field Lattice Boltzmann Method," under review.
C. Zhao, V. Kern, A. Carlson, and T. Lee, "Engulfment of a Drop on Solids Coated by Thin and Thick Fluid Films," Journal of Fluid Mechanics 958: A41 (2023) https://doi.org/10.1017/jfm.2023.110
M. Borumand, T. Lee, and G. Hwang, "Enhanced Wickability in Single- and Three-Columnar Bi-Particle Size Wicks using Multiphase Lattice Boltzmann Method," Computers & Fluids 255: 105831 (2023) https://doi.org/10.1016/j.compfluid.2023.105831
C. Zhao and T. Lee, "Interaction between a Rising Bubble and a Droplet Immersed in a Liquid Pool using Ternary Conservative Phase-field Lattice Boltzmann Method," Physical Review E 107: 025308 (2023) https://doi.org/10.1103/PhysRevE.107.025308
M. Borumand, T. Lee, and G. Hwang, "Enhanced Wickability through Non-uniform Pore Size Wick using Lattice Boltzmann Method," Computers & Fluids 238: 105376 (2022) https://doi.org/10.1016/j.compfluid.2022.105376
G. Liu and T. Lee, “Diffuse Bounce Back Condition for Lattice Boltzmann Method,” Computers & Fluids 220: 104884 (2021) https://doi.org/10.1016/j.compfluid.2021.104884
L. Baroudi and T. Lee, “Simulation of a Bubble Rising at High Reynolds Number with Mass-conserving Finite Element Lattice Boltzmann Method,” Computers & Fluids 220: 104883 (2021) https://doi.org/10.1016/j.compfluid.2021.104883
L. Baroudi and T. Lee, “Effect of Interfacial Mass Transport on Inertial Spreading of Liquid Droplets,” Physics of Fluids 32: 032101 (2020) https://doi.org/10.1063/1.5135728
M. Mohammadi-Shad and T. Lee, “Lattice Boltzmann Modeling of Boiling Using a Sharp Interface Energy Solver,” Physical Review E 96: 013306 (2017)
S. Farokhirad and T. Lee, “Computational Study of Microparticle Effects on Self-Propelled Jumping of Droplets on Superhydrophobic Substrates,” International Journal of Multiphase Flow 95: 220–234 (2017)
S. Farokhirad, M. Mohammadi-Shad, and T. Lee, “Computational Study of Self-propelled Jumping of Droplets on Micro-structured Superhydrophobic Substrates,” European Journal of Computational Mechanics 26: 205–223 (2017)
R. Chen, H. Yu, L. Zhu, R.M. Patil, and T. Lee, “Spatial and Temporal Scaling of Unequal Microbubble Coalescence,” AIChE Journal 63: 1441–1450 (2017)
S.S. Patel and T. Lee, “A New Splitting Scheme to the Discrete Boltzmann Equation for Non-ideal Gases on Non-uniform Meshes,” Journal of Computational Physics 327: 799–809 (2016)
S.S. Patel, M. Min, and T. Lee, “Spectral Element Discontinuous Galerkin Simulation of Conjugate Heat Transfer with Heat Source,” International Journal for Numerical Methods in Fluids 82: 932–952 (2016)
L. Baroudi, S.R. Nagel, and T. Lee, “Comment on “Viscous Coalescence of Droplets: A Lattice Boltzmann Study” [Phys. Fluids 25, 052101 (2013)],” Physics of Fluids 28: 079101 (2016)
A. Fakhari, M.C. Geier, and T. Lee, “A Mass-conserving Lattice Boltzmann Method with Dynamic Grid Refinement of Immiscible Two-phase Flows,” Journal of Computational Physics 315: 434–457 (2016)
I. Bischofberger, B. Ray, J.F. Morris, T. Lee, and S.R. Nagel, “Air Flows Generated by an Impacting Drop,” Soft Matter 12: 3013–3020 (2016)
X. Jiang, Y. Andreopoulos, T. Lee, and Z. Wang, “Numerical Investigations on the Vortex-Induced Vibration of Moving Square Cylinder by Using Incompressible Lattice-Boltzmann Method,” Computers & Fluids 124: 270–277 (2016)
L. Baroudi, S.R. Nagel, J.F. Morris, and T. Lee, “Dynamics of Viscous Coalescing Droplets in a Saturated Vapor Phase,” Physics of Fluids 27: 121702 (2015)
S. Farokhirad, J.F. Morris, and T. Lee, “Effects of Inertia and Viscosity on the Coalescence-Induced Self-Propelled Jumping of Droplet on Super-hydrophobic Surfaces,” Physics of Fluids 27: 102102 (2015)
K.W. Connington, M. Miskin, T. Lee, J.F. Morris, and H. Jaeger, “Lattice Boltzmann Simulations of Particle-laden Liquid Bridges: Effect of Volume Fraction and Wettability,” International Journal of Multiphase Flow 76: 32–46 (2015)
M.C. Geier, A. Fakhari, and T. Lee, “Conservative Phase-field Lattice Boltzmann Equation for Interface Tracking,” Physical Review E 91: 063309 (2015)
K.W. Connington, T. Lee, and J.F. Morris, “Interaction of Fluid Interfaces with Immersed Solid Particles using the Lattice Boltzmann Method,” Journal of Computational Physics 283: 453–477 (2015)
A. Fakhari and T. Lee, “Numerics of the Lattice Boltzmann Method on Nonuniform Grids: Standard LBM and Finite-difference LBM,” Computers & Fluids 107: 205–213 (2015)
R. Zhang, S. Farokhirad, T. Lee, and J. Koplik, “Multiscale Liquid Drop Impact on Wettable and Textured Surfaces,” Physics of Fluids 26: 082003 (2014)
A. Fakhari and T. Lee, “A Finite Difference Lattice Boltzmann Model with a Block-structured Adaptive Mesh Refinement Technique,” Physical Review E 89: 033310 (2014)
S.S. Patel, M. Min, K.C. Uga, and T. Lee, “Spectral-Element Discontinuous Galerkin Lattice Boltzmann Method for Simulating Natural Convection Heat Transfer in a Horizontal Concentric Annulus,” Computers & Fluids 95: 197–209 (2014)
L. Zheng, T. Lee, Z. Guo, and D. Rumschitzki, “Shrinkage of Bubbles/Drops in the Lattice Boltzmann Equation Method for Nonideal Gases,” Physical Review E 89: 033302 (2014)
R. Samaroo, N. Kaur, K. Itoh, T. Lee, S. Banerjee, and M. Kawaji, “Turbulent Flow Characteristics in an Annulus under Air Bubble Injection and Subcooled Flow Boiling Conditions,” Nuclear Engineering & Design 268: 203–214 (2014)
L. Baroudi, M. Kawaji, and T. Lee, “Effects of Initial Conditions on the Simulation of Inertial Coalescence of Two Drops,” Computers & Mathematics with Applications 67: 282–289 (2014)
K.W. Connington and T. Lee, “Lattice Boltzmann Simulations of Forced Wetting of Drops on Superhydrophobic Surfaces,” Journal of Computational Physics 250: 601–615 (2013)
A. Fakhari and T. Lee, “Multiple-Relaxation-Time Lattice Boltzmann Method for Immiscible Fluids at High Reynolds Numbers,” Physical Review E 87: 023304 (2013)
S. Farokhirad, T. Lee, and J.F. Morris, “Effects of Inertia and Viscosity on Single Droplet Deformation in Confined Shear Flow,” Communications in Computational Physics 13: 706–724 (2013)
K.C. Uga, M. Min, T. Lee, and P.F. Fischer, “Lattice Boltzmann Simulations of Flow Past Two Cylinders in Tandem using Spectral-Element Discontinuous Galerkin Approach with Exponential Time Integrator,” Computers & Mathematics with Applications 65: 239–251 (2013)
K.E. Wardle and T. Lee, “Finite Element Lattice Boltzmann Simulations of Free Surface Flow in a Concentric Cylinder,” Computers & Mathematics with Applications 65: 230–238 (2013)
K.W. Connington and T. Lee, “A Review of the Occurrence of Spurious Velocities in the Lattice Boltzmann Method for Multiphase Flows,” Journal of Mechanical Science and Technology 26: 3857–3863 (2012)
M. Min and T. Lee, “A Spectral Element Discontinuous Galerkin Lattice Boltzmann Method for Nearly Incompressible Flows,” Journal of Computational Physics 230: 245–259 (2011)
L. Amaya and T. Lee, “Numerical Simulation of Bubble Formation in Microchannels with T-Junction,” Philosophical Transactions of Royal Society A 369: 2405–2413 (2011)
L. Amaya and T. Lee, “Numerical Simulation of Single Bubble Rising in Vertical and Inclined Square Channel using Lattice Boltzmann Method,” Chemical Engineering Science 66: 935–952 (2011)
T. Lee and L. Liu, “Lattice Boltzmann Simulations of Micron-scale Drop Impact on Dry Surfaces,” Journal of Computational Physics 229: 8045–8063 (2010)
L. Amaya and T. Lee, “Single Bubble Rising Dynamics for Moderate Reynolds Number using Lattice Boltzmann Method,” Computers & Fluids 39: 1191–1207 (2010)
L. Liu and T. Lee, “Wall Free Energy Based Polynomial Boundary Conditions for Non-ideal Gas Lattice Boltzmann Equation,” International Journal of Modern Physics C 20: 1749–1768 (2009)
T. Lee, “Effects of Incompressibility on the Elimination of Parasitic Currents in the Lattice Boltzmann Equation Method for Binary Fluids,” Computers & Mathematics with Applications 58: 987–994 (2009)
T. Lee and G.K. Leaf, “Eulerian Description of High-order Bounce-back Scheme for Lattice Boltzmann Equation with Curved Boundary,” The European Physical Journal–Special Topics 171: 3–8 (2009)
T. Lee and L. Liu, “Wall Boundary Conditions in the Lattice Boltzmann Equation Method for Nonideal Gases,” Physical Review E 78: 017702 (2008)
T. Lee, C.-L. Lin, and C.A. Friehe, “Large-Eddy Simulation of Air Flow around a Wall-Mounted Circular Cylinder and a Tripod Tower,” Journal of Turbulence 8: N29 (2007)
T. Lee and P.F. Fischer, “Eliminating Parasitic Currents in Lattice Boltzmann Equation Method for Non-ideal Gases,” Physical Review E 74: 046709 (2006)
T. Lee, C.-L. Lin, and L.-D. Chen, “A Lattice Boltzmann Algorithm for Calculation of the Laminar Jet Diffusion Flame,” Journal of Computational Physics 215: 133–152 (2006)
C.-L. Lin, H. Lee, T. Lee, and L. Weber, “A Level Set Characteristic Galerkin Finite Element Method for Free Surface Flows,” International Journal for Numerical Methods in Fluids 49: 521–547 (2005)
T. Lee and C.-L. Lin, “A Stable Discretization of the Lattice Boltzmann Equation Method for Simulation of Incompressible Two-Phase Flows at High Density Ratio,” Journal of Computational Physics 206: 16–47 (2005)
T. Lee and C.-L. Lin, “Rarefaction and Compressibility Effects of the Lattice Boltzmann Equation Method in a Gas Microchannel,” Physical Review E 71: 046706 (2005)
T. Lee and C.-L. Lin, “A Pressure Evolution Lattice Boltzmann Equation Method for Two-Phase Flow with Phase Change,” Physical Review E 67: 056703 (2003)
T. Lee and C.-L. Lin, “An Eulerian Description of the Streaming Process in the Lattice Boltzmann Equation,” Journal of Computational Physics 185: 445–471 (2003)
T. Lee and C.-L. Lin, “A Characteristic Galerkin Method for Discrete Boltzmann Equation,” Journal of Computational Physics 171: 336–356 (2001)