Lectures related to Thermodynamics and phase space sampling

Canonical Ensemble: Partition Function and Ideal Gas

Explores the canonical ensemble, partition function, and ideal gas properties.

Explores the role of thermodynamics in cell biology, focusing on the connection between thermodynamics and cellular processes.

Canonical Ensemble: Probability Distribution

Explores the probability distribution in the canonical ensemble and the Boltzmann distribution.

Thermodynamics in Cell Biology

Explores the role of thermodynamics in cell biology, discussing its universality, predictions, and application in cellular processes near equilibrium.

Molecular Dynamics: Sampling and Thermostats

Explores molecular dynamics sampling, conservation laws, energy fluctuations, and various thermostats used for simulations.

Entropy and the Second Law of Thermodynamics

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

Introduction to Thermodynamics

Covers the fundamentals of classical physics, emphasizing energy transformations in systems through gas laws, work, heat, and the laws of thermodynamics.

Path Integral Methods: Efficient Energy Estimators

Covers advanced path integral methods for deriving efficient energy estimators in molecular dynamics simulations.

Chemical Equilibria and Reactivity

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

Atomistic Computer Modelling of Materials: Simulating and Sampling

Covers simulating and sampling in atomistic computer modelling of materials.

Ensembles and Partition Functions

Covers ensembles, partition functions, and distributions in statistical thermodynamics.

Sampling the Canonical Ensemble

Explores sampling the canonical ensemble, temperature fluctuations, extended Lagrangian, and Maxwell-Boltzmann distribution in molecular dynamics simulations.

Entropy and Thermodynamics: Microstates and Macrostates

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

Classical Thermodynamics: Fundamentals

Covers the fundamentals of classical thermodynamics, from classical mechanics to statistical mechanics, and key thermodynamic variables.

Maxwell's Gas Theory: Formation Temperature of Earth

Covers Maxwell's gas theory, focusing on ideal gas behavior and Earth's formation temperature analysis.

Thermodynamic Potentials: Lagrangian Mechanics and Energy Relations

Discusses the transition from Hamiltonian to Lagrangian mechanics, focusing on thermodynamic potentials and their implications in energy transformations.

Physics Principles and Mechanics

Explores fundamental physics principles, with a focus on mechanics and thermodynamics, emphasizing real-world applications.

Molecular dynamics under constraints

Explores molecular dynamics simulations under holonomic constraints, focusing on numerical integration and algorithm formulation.

Entropy and the Joule Expansion: A Statistical Perspective

Covers the relationship between entropy and the Joule expansion, illustrating how microscopic states relate to macroscopic disorder.

Calorimetric Coefficients

Covers the definitions and relationships between calorimetric coefficients in perfect gases.