Xi-Yun Lu mostly deals with Mechanics, Classical mechanics, Lattice Boltzmann methods, Vortex and Flow. His study ties his expertise on Immersed boundary method together with the subject of Mechanics. His study in Classical mechanics is interdisciplinary in nature, drawing from both Drag coefficient, Cylinder, Rotation, Potential flow around a circular cylinder and Navier–Stokes equations.
His research integrates issues of Numerical stability, HPP model, Statistical physics, Porous medium and Incompressible flow in his study of Lattice Boltzmann methods. His studies deal with areas such as Leading edge and Wake as well as Vortex. Xi-Yun Lu combines subjects such as Non-Newtonian fluid, Secondary flow, Newtonian fluid and Vortex shedding with his study of Flow.
His primary scientific interests are in Mechanics, Classical mechanics, Turbulence, Reynolds number and Lattice Boltzmann methods. His work on Mechanics is being expanded to include thematically relevant topics such as Flapping. The various areas that Xi-Yun Lu examines in his Flapping study include Thrust, Propulsion, Flexibility, Flow and Wake.
His Classical mechanics research incorporates elements of Flow, Navier–Stokes equations, Compressibility, Compressible flow and Rotation. His Reynolds number research includes elements of Amplitude and Drag coefficient. His research investigates the link between Lattice Boltzmann methods and topics such as Fluid dynamics that cross with problems in Elastic energy.
Xi-Yun Lu focuses on Mechanics, Flapping, Turbulence, Drop and Classical mechanics. Xi-Yun Lu regularly links together related areas like Bending stiffness in his Mechanics studies. His work deals with themes such as Propulsion, Propulsive efficiency, Deformation, Amplitude and Wake, which intersect with Flapping.
His Turbulence study integrates concerns from other disciplines, such as Work and Vorticity. His Classical mechanics study combines topics in areas such as Lattice Boltzmann methods and Stability theory. His Lattice Boltzmann methods research is multidisciplinary, relying on both Fluid dynamics, Thermal and Bubble.
Xi-Yun Lu spends much of his time researching Mechanics, Flapping, Drop, Wetting and Propulsion. The Mechanics study combines topics in areas such as Amplitude and Classical mechanics, Inertia. The study incorporates disciplines such as Flow, Tube and Hagen–Poiseuille equation in addition to Classical mechanics.
His Flapping research is multidisciplinary, incorporating perspectives in Fluid dynamics, Leading edge, Power and Propulsive efficiency. He has included themes like Contact angle, Surface tension, Harmonic vibration, Climbing and Wetted area in his Drop study. The concepts of his Wetting study are interwoven with issues in Dimple, Capillary action, Capillary number, Lubrication theory and Viscous liquid.
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Post-stall flow control on an airfoil by local unsteady forcing
Jie-Zhi Wu;Xi-Yun Lu;Andrew G. Denny;Meng Fan.
Journal of Fluid Mechanics (1998)
Multiphase Lattice Boltzmann Methods: Theory and Application
Haibo Huang;Michael C. Sukop;Xi-Yun Lu.
Multiphase Lattice Boltzmann Methods: Theory and Application: Huang/Multiphase Lattice Boltzmann Methods: Theory and Application
Haibo Huang;Michael C. Sukop;Xi-Yun Lu.
An efficient immersed boundary-lattice Boltzmann method for the hydrodynamic interaction of elastic filaments
Fang-Bao Tian;Haoxiang Luo;Luoding Zhu;James C. Liao.
Journal of Computational Physics (2011)
Forcing term in single-phase and Shan-Chen-type multiphase lattice Boltzmann models.
Haibo Huang;Haibo Huang;Manfred Krafczyk;Xiyun Lu.
Physical Review E (2011)
Integral force acting on a body due to local flow structures
J.-Z. Wu;X.-Y. Lu;L.-X. Zhuang.
Journal of Fluid Mechanics (2007)
Numerical investigation of the non-Newtonian blood flow in a bifurcation model with a non-planar branch.
Jie Chen;Xi-Yun Lu.
Journal of Biomechanics (2004)
Characteristics of flow over traveling wavy foils in a side-by-side arrangement
Gen-Jin Dong;Xi-Yun Lu.
Physics of Fluids (2007)
Evaluation of three lattice Boltzmann models for multiphase flows in porous media
Haibo Huang;Lei Wang;Xi-yun Lu.
Computers & Mathematics With Applications (2011)
Non-Newtonian effects of blood flow on hemodynamics in distal vascular graft anastomoses.
Jie Chen;Xi-Yun Lu;Wen Wang.
Journal of Biomechanics (2006)
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