Lectures related to Dynamical Theory: Nanoparticle Systems

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

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.

Heat Transfer Fundamentals

Covers the fundamentals of heat transfer, focusing on radiation, conduction, and convection, including boundary layers and Nusselt number.

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.

Introduction to Free Convection: Governing Equations

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

Fundamental Equations: Conservation and Thermodynamics

Covers mass, momentum, energy conservation, and thermodynamics in fluid dynamics.

Conservation of Momentum and Kinetic Energy

Explores conservation of momentum and kinetic energy in collisions, emphasizing the importance of understanding collision outcomes.

Quantité de mouvement and Impulsion

Explores momentum, impulse, work, energy, and angular momentum in advanced physics.

Classical Equations and Conservation Laws

Explores classical equations, conservation laws, and quantum distributions in various systems, shedding light on particle behavior.

Fluid Dynamics: Equations and State

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

Straight Shocks: General Equations

Discusses mass, momentum, and energy conservation in straight shock waves.

The Finite Volume Method

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

Material and Energy Balances

Explores material and energy balances in chemical engineering for process optimization and design.

Conservation Laws in Plasma Physics

Covers the conservation laws in plasma physics, highlighting entropy, energy, and momentum conservation.

Conservation Equations in Fluid Dynamics

Covers the derivation of conservation equations in fluid dynamics and their practical applications in engineering problems.

Magnetic Flux Freezing

Explains magnetic flux freezing and the transition to a 1-fluid model in plasma dynamics.

The Finite Volume Method in 2D/3D

Introduces the finite volume method, conservation equations, and numerical flow simulation for steady diffusion in 2D/3D.

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Introduction to Transport Phenomena: Bernoulli's Equation

Covers Bernoulli's equation and its applications in fluid flow problems, including continuity, friction factors, and practical examples.

Elastic Collisions: Conservation Laws and Kinetic Energy

Explores the analysis of collisions, conservation laws, and kinetic energy exchange in elastic collisions between two bodies.