Covers fundamental hydrodynamics concepts, including two-phase flows, turbulence, and practical CFD examples.
Explores turbulence characteristics, simulation methods, and modeling challenges, providing guidelines for choosing and validating turbulence models.
Explores the Bernoulli equation in fluid dynamics, emphasizing assumptions and practical applications in solving fluid mechanics problems.
Explores the concept of stationary distribution in Markov chains, discussing its properties and implications, as well as the conditions for positive-recurrence.
Explores dynamic boundary conditions in fluid mechanics, perturbation techniques, and fluid stability analysis.
Explores fluid friction forces, including laminar and turbulent flow, viscosity, and terminal velocity calculation.
Covers drag reduction, two-phase flows, geophysics, tidal energy harvesting, fish propulsion, flow classifications, instabilities, turbulence, and computational tools.
Explores forced external convection correlations and the procedure for solving convection problems, including the comparison of velocity and thermal boundary layers.
