Lectures related to Dispersion Models: Behavior and Criteria

Chemical Engineering of Heterogeneous Reactions

Covers the basics of chemical engineering of heterogeneous reactions and introduces Laplace transforms to simplify complex problems.

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Dispersion Models: Understanding Axial Dispersion Coefficient

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

Chemical Reaction Engineering: Conversion and Reactor Sizing

Explores the algorithm for solving chemical reaction engineering problems, focusing on conversion and reactor sizing.

Complex Systems: Epidemics

Delves into complex systems, strange attractors, and epidemics, emphasizing the influence of psychological factors and the role of contagion.

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.

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Chemical reaction engineering

Explores chemical reaction engineering fundamentals, reactor design, and variable flow rates.

Chemical reaction engineering: reactor design

Focuses on isothermal reactor design, covering mole balances, rate laws, stoichiometry, and pressure drop effects.

Fluid Segregation in Chemical Reactors

Explores fluid segregation in chemical reactors, discussing its impact on conversion rates and reactor performance.

Chemical Reaction Engineering: Algorithmic Approach

Explores problem-solving algorithms for chemical reactor design and analysis, emphasizing the CRE approach and various reactor configurations.

Transport Effects in Heterogeneous Catalysis

Explores transport effects in heterogeneous catalysis, emphasizing the impact of mass transfer on reaction kinetics and mechanisms.

Turbulence: Numerical Flow Simulation

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

Chemical reaction engineering: reactor design

Explores the Chemical Reaction Engineering algorithm applied to isothermal reactor design, with examples on SO2 oxidation and N2O4 decomposition.

Fluid Friction Forces

Explores fluid friction forces, including laminar and turbulent flow, viscosity, and terminal velocity calculation.

Miniaturization: Impact on Chemical Reactions and Mixing

Covers miniaturization in chemical engineering, focusing on mixing effects on reactions and process efficiency.

Laminar and Turbulent Flow

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

Chemical Reaction Engineering: Algorithm and Stoichiometry

Explores the Chemical Reaction Engineering algorithm in batch reactors and CSTRs, focusing on stoichiometry and rate laws.

Internal Forced Convection: Hydrodynamic Aspects

Covers the hydrodynamic and thermal aspects of internal forced convection.

Chemical Reaction Engineering: Reactor Design

Explores chemical kinetics, reactor design, and critical thinking in chemical reaction engineering.