Lectures related to Quantum Perturbation Theory

Covers quantum eigenfunctions and the importance of A and B commuting for the same set of eigenfunctions.

Covers the measurement of observable eigenvalues and the importance of complete orthonormal sets.

Explores the Eigenstate Thermalization Hypothesis in quantum systems, emphasizing the random matrix theory and the behavior of observables in thermal equilibrium.

Quantum Chemistry: Fundamentals of Quantum Mechanics

Covers the fundamentals of quantum mechanics and the behavior of particles at the quantum level.

Quantum Mechanics: Hilbert Space and Operators

Covers the fundamental concepts of quantum mechanics, focusing on Hilbert spaces and operators.

Quantum Field Theory: Fermions and Grassmann Numbers

Explores quantum field theory, focusing on fermions and Grassmann numbers in the path integral formalism.

Stochastic Models: Absorbing Markov Chains Examples

Covers examples of absorbing Markov chains in discrete time.

Quantum Langevin Equations

Covers the derivation of quantum Langevin equations and input-output formalism in open quantum systems.

Quantum Effective Action

Explores the quantum effective action, its role in perturbation theory, and the organization of correlators in momentum space.

Effective Field Theory: Testing Weak Interactions

Explores effective field theory for testing weak interactions and parity violation through forward-backward asymmetry.

Discrete-Time Markov Chains: Absorbing Chains Examples

Explores examples of absorbing chains in discrete-time Markov chains, focusing on transition probabilities.

Discrete-Time Markov Chains: Absorbing Chains Examples

Covers examples of absorbing chains in discrete-time Markov chains.

Quantum Random Number Generation

Explores quantum random number generation, discussing the challenges and implementations of generating good randomness using quantum devices.

Quantum Field Theory: Loop Corrections and Counter Terms

Explores loop corrections and counter terms in quantum field theory, showcasing how divergences are handled and predictions are extracted from loop calculations.

Separation of Variables

Explores the concept of separation of variables in quantum mechanics and its application in solving differential equations.

Quantum Approximate Optimization Algorithm

Covers the Quantum Approximate Optimization Algorithm, physically inspired unitary coupled cluster ansatz, hardware-efficient ansatz, and variational quantum eigensolver.

Quantum Optics I: Stern-Gerlach Experiment

Explores the Stern-Gerlach experiment, strong measurements, cavity quantum electrodynamics, and quantum optomechanics.

Quantum Reservoir Engineering

Explores Quantum Reservoir Engineering, energy relaxation, and quantum phasing in systems, discussing equations of motion and spectral densities.

Numerical Methods: Runge-Kutta Approximation

Covers the Runge-Kutta method for approximating solutions of differential equations.

Quantum Entanglement

Delves into quantum entanglement, exploring entangled particles' state, evolution, and measurement.