Lectures related to Energy Minimization in Biological Systems: Equilibrium Models

Explores the Second Law of Thermodynamics, Gibbs Free Energy, equilibrium constants, and Le Châtelier's Principle.

Entropy and the Second Law of Thermodynamics

Covers entropy, its definition, and its implications in thermodynamics.

Phase Equilibria: Understanding Vapor-Liquid Separation

Provides an overview of vapor-liquid phase diagrams and their role in separation processes, focusing on phase equilibria and the Gibbs phase rule.

Thermodynamics II: Entropy and Gibbs Energy

Explores entropy, Gibbs energy, spontaneity of reactions, and equilibrium constants in thermodynamics.

Protein Folding: Thermodynamic Insights

Delves into the energetic determinants of protein folding, equilibrium constants, and thermodynamic properties of proteins, emphasizing enthalpy, entropy, and heat capacity.

Phase Transitions: Understanding Thermodynamic Stability

Explores phase transitions in thermodynamics, focusing on stability criteria and real-world applications.

Entropy and Thermodynamics: Microstates and Macrostates

Covers the concepts of microstates and macrostates in thermodynamics, focusing on entropy and its implications for isolated systems.

Thermodynamics: Energy Transformation

Covers energy transformation in thermodynamics, discussing laws, entropy, and spontaneity criteria for reactions.

Chemical Equilibria and Reactivity

Covers the concepts of energy types, entropy, second principle, and Gibbs free energy.

Thermodynamics: Exploring Thermodynamic Potentials and Equilibrium States

Covers thermodynamic potentials and their role in system equilibrium with reservoirs.

Polymer Collapse: Covolume and Free Energy

Explores polymer collapse, emphasizing covolume and free energy in the process.

Chemical Thermodynamics: Entropy and Gibbs Energy

Explores chemical thermodynamics, entropy, enthalpy, Gibbs energy, and chemical equilibrium.

Thermodynamics: Entropy and Gibbs Free Energy

Explores thermodynamics, entropy, and Gibbs free energy to predict reaction spontaneity and understand absolute entropy.

Protein Folding: Non-equilibrium Dynamics

Explores protein folding dynamics, focusing on chaperone-assisted non-equilibrium stabilization and its implications for biophysics and evolution.

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Chemical Potential and Thermodynamic Functions in Mixtures

Covers chemical potential variations and thermodynamic functions in mixtures, emphasizing their implications in real and ideal gases.

Thermodynamics: Entropy and Spontaneity in Reactions

Provides an overview of thermodynamic principles, focusing on entropy, spontaneity, and chemical equilibrium.

Thermodynamics: Entropy and Ideal Gases

Explores entropy, ideal gases, and TDS equations in thermodynamics, emphasizing the importance of the Clausius inequality and the Carnot cycle.

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