Lectures related to Time-dependent perturbation theory part 2 and path integral part 1

Explores second-order perturbation theory in quantum physics for transition probabilities and rates.

Explores time-dependent perturbation theory in quantum physics from an interaction point of view.

Explores transition probabilities in first-order perturbation theory with time-dependent perturbations and disturbance theory.

Explores time-independent perturbations in quantum physics, covering variational principle and Fourier series.

Covers the theory of time-independent perturbations in the degenerate case.

Covers the ground-state quantum Monte Carlo method and its statistical interpretation.

Covers path-integral ground state methods and Monte Carlo simulations in computational quantum physics.

Explores non-perturbative effects in quantum physics, focusing on instantons in the double well potential.

Explores the physical interpretation of the Schur lemma in quantum physics.

Covers the concept of scattering theory and its application to non-relativistic collisions and collider experiments.

Explores perturbation theory, proper states, undegenerated states, and problem-solving in quantum bosons.

Explores time-independent perturbation theory in the degenerate case within quantum physics.

Explores the dilute instanton gas approximation and the importance of multi-instanton solutions in quantum field theory.

Covers projectors on invariant subspaces in quantum physics and their applications.

Explores optics problems in quantum physics, focusing on interference patterns and phase differences.

Covers the concept of path integral in quantum physics, focusing on phase space path integral and real space path integral.

Explores the historical development of quantum mechanics and information theory, focusing on the double slit experiment and quantum phenomena.

Explores wave functions in quantum physics, focusing on superposition and particle behavior.

Covers quantum computing basics, quantum algorithms, error correction, and quantum bit manipulation.

Explores quantum physics, wave-particle duality, and optical phenomena like reflection and interference.