Introduces turbulence and symmetry in fluid dynamics, exploring the effects of Reynolds number on flow patterns.
Explores Poiseuille's law, pressure-velocity relation, wall shear stress, resistances, Bernoulli's equation, and turbulence in fluid dynamics.
Explores turbulence characteristics, simulation methods, and modeling challenges, providing guidelines for choosing and validating turbulence models.
Explores turbulence characteristics, modeling challenges, and various numerical simulation methods.
By the instructor Tobias Schneider explores the fundamental aspects of turbulence and its significance in various scientific disciplines.
Explores the interpretation and decay of turbulence, dissipation scales, and the restoration of symmetries in fluid dynamics.
Explores buckling of structural members, including columns under compressive loads and the transition to turbulence in fluid flows.
Explores the hierarchy of simulation approaches in fluid dynamics and the challenges in determining Reynolds stresses.
Explores fluid oscillators and amplifiers, covering nonlinear dynamics, frequency corrections, Reynolds stresses, and bifurcation theory.
Explores the restoration of symmetries in fluid dynamics equations, particularly the Navier-Stokes equations in periodic domains, highlighting the significance of symmetry in understanding fluid motion.
Delves into vorticity, circulation, and vortex characteristics, impacting fluid behavior and system performance.
