Path integrals and statistical mechanics

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Related lectures (31)

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Path Integral Methods: Efficient Energy Estimators

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

Molecular dynamics under constraints

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

Statistical Physics: Entropy

Explores statistical physics concepts like equiprobable microstates, entropy, and canonical ensembles, with applications in quantum mechanics and semiconductor physics.

Sampling the Canonical Ensemble

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

Quantum to Classical Mechanics: Fundamentals

Covers the transition from quantum to classical mechanics, statistical mechanics, Monte Carlo simulations, and molecular dynamics simulations.

Statistical Thermodynamics: Partition Functions and Quantum Statistics

Introduces partition functions, quantum statistics, and the Einstein model for molecular behavior.

Atomistic Computer Modelling of Materials: Simulating and Sampling

Covers simulating and sampling in atomistic computer modelling of materials.

Bose-Einstein Statistics: Derivation and Applications

Explores the derivation and application of Fermi and Bose statistics in different ensembles.

Quantum Mechanics Evolution

Explains the representation for evolution in quantum mechanics and the application of path integrals.

Path Integral Methods: Advanced Momentum Estimators

Covers the derivation of path integral estimators for momentum-dependent operators and discusses improvements for statistical convergence in multi-particle systems.