Lectures related to Navier-Stokes: Numerical Flow Simulation

Explores the challenges of Navier-Stokes equations, pressure checkerboard, staggered grid, and the SIMPLE algorithm.

Navier-Stokes Equations: Numerical Flow Simulation

Explores challenges and solutions in numerical flow simulation, emphasizing the importance of physical consistency in computational fluid dynamics.

Turbulence: Numerical Flow Simulation

Explores turbulence characteristics, simulation methods, and modeling challenges, providing guidelines for choosing and validating turbulence models.

Linear Momentum Conservation and Stress in Continuum

Explores the conservation of linear momentum and stress in a continuum, focusing on governing equations and constitutive laws.

Inviscid Flows: Understanding Fluid Dynamics

Explores inviscid flows, Reynolds number importance, linear deformations, and volume change in fluid dynamics.

Turbulence in Astrophysics: Reynolds Decomposition

Covers the modeling of fluid instabilities with linear perturbation theory and explores the origin of unpredictability in turbulence through the Navier-Stokes equations.

Symmetries and Conservation Laws

Covers symmetries and conservation laws in fluid dynamics, emphasizing the importance of maximizing symmetries in ideal fluid systems.

Viscous flow: Equations and Solutions

Explores equations and solutions for viscous flow, including stress-deformation relationships, Navier-Stokes equations, and simple fluid flow cases.

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Fluid Dynamics: Navier-Stokes Equations

Explores fluid dynamics, covering Navier-Stokes equations, momentum conservation, stresses, and dimensional analysis.

Fluid Dynamics: Differential Conservation Laws and Equations

Covers the differential approach to fluid dynamics, focusing on conservation laws and the Cauchy stress tensor.

Fluid Dynamics: Equations and State

Explores fluid dynamics concepts like energy argument, momentum balance, and equation of state for perfect fluids.

Incompressible Fluid Mechanics: Differential Analysis

Covers mass and momentum conservation, Navier-Stokes equations, and analytical methods in incompressible fluid mechanics.

Introduction to Free Convection: Governing Equations

Explores free convection, laminar flow boundary layer equations, and heat transfer principles.

Fluid Dynamics: Ideal Fluids

Explores physical models for microsystems, ideal fluids, Navier-Stokes equations, incompressible fluids, Reynolds number, and molecular dynamics.

Shock Wave Formation: Theory

Covers the theory of shock wave formation in isentropic flow.

Dynamical Theory: Nanoparticle Systems

Covers constructing a dynamical theory for nanoparticle systems, conservation equations, and transport phenomena.

Stochastic a-Navier-Stokes Model: Properties and Applications

Explores the stochastic a-Navier-Stokes model for fluid dynamics and its applications in various contexts.

The Finite Volume Method

Covers the Finite Volume Method for numerical flow simulation, including conservation equations, discretization methods, and boundary conditions.

Astrophysical Fluids & Plasmas

Explores the composition of the cosmos, dynamics of fluids and plasmas, and conservation equations.