Lectures related to Phenomenology of Energy Cascade

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

Turbulence Modeling: Reynolds Stress Models

Explores the k-e model for turbulent flows and Reynolds stress models.

Diffusion in Fluids: Understanding Mass Transport

Covers diffusion, focusing on mass transport in fluids and its mathematical formulation.

Diffusion and Convection Transport

Explores the microscopic description of diffusion and convection transport, emphasizing similarities between chemical diffusion and heat conduction.

Turbulence: Numerical Flow Simulation

Explores the challenges of turbulence, simple turbulent flows, and numerical simulation methods.

Turbulence Concepts: Reynolds Decomposition and Closure Problem

Explores Reynolds decomposition, closure problem, and turbulence modeling challenges.

Fluid Mechanics: Foundations and Applications

Covers the foundations of fluid mechanics, focusing on flow problem descriptions and solutions.

Turbulence: Modeling and Simulation

Explores turbulence modeling in fluid dynamics, covering RANS equations, various turbulence models, and their implementation in numerical simulations.

Untitled

Laminar and Turbulent Flow

Covers laminar and turbulent flow, pressure losses, Reynolds number, Poiseuille flow, and friction in piping networks.

Diffusion and transport in tokamak plasmas

Covers diffusive transport in tokamak plasmas, including classical and neo-classical diffusion, ambipolar diffusion, and turbulent transport.

Dispersion Models: Understanding Axial Dispersion Coefficient

Explores dispersion models and the axial dispersion coefficient in fluid systems.

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.

Internal Forced Convection: Hydrodynamic Aspects

Covers the hydrodynamic and thermal aspects of internal forced convection.

Pressure Drop in Closed-Flow Systems

Explores pressure drop in closed-flow systems, including minor losses and exercises on fluid transfer and pump power.

Mixing in Microchannels

Explores flow regimes, diffusion mixing, and energetic efficiency in microchannels, emphasizing the need for fast mixing with minimal energy.

Fluid Oscillators & Amplifiers

Explores fluid oscillators and amplifiers, covering nonlinear dynamics, frequency corrections, Reynolds stresses, and bifurcation theory.

Fluid Dynamics: Reynolds Number and Flow Characteristics

Covers the Reynolds number, flow characteristics, mass flow, and continuity equations in fluid dynamics.

Computational Geomechanics: Week 4

Explores transient flow in porous media, covering governing equations, stability conditions, and numerical methods.