Lectures related to Relativistic quantum mechanics

Physics Fundamentals: Laws and Observations

Covers the fundamentals of physics, including laws, predictions, corrections, and the role of observers.

Quantum Field Theory: Normalization and Lorentz Invariance

Explores the relativistic normalization of states in quantum field theory.

Explores Fourier modes in Quantum Field Theory, emphasizing variables transforming well under translations and the normalization of states.

Scalar, Vector or Tensor? Gravity

Discusses defining tensors, space-time dimensionality, and challenges in formulating a relativistic theory of gravity.

Synchrotron Radiation

Covers the properties of synchrotron radiation, including its emission by relativistic particles and its effect on the beam through radiation damping.

Quantum Physics III: Introduction to Relativistic Quantum Mechanics

Introduces relativistic quantum mechanics, Dirac equation, positron prediction, and quantum states properties.

Quantum Field Theory: Introduction

Introduces Quantum Field Theory as the way to reconcile Quantum Mechanics with Relativity, emphasizing the need for a local field due to the impossibility of instantaneous interactions at a distance.

Relativistic Formulation of Newtonian Mechanics

Explores the Lorentz covariant formulation of Newtonian mechanics, including 4-vectors and relativistic Newton's second law.

Variational Method in Relativistic Quantum Field Theory

Delves into the variational method in relativistic quantum field theory without cutoff, emphasizing weakly entangled states and the transition to relativistic continuous matrix product states.

Quantum Field Theory: Lecture 9

Covers relativistically normalized states, Lorentz invariance, and scalar field representations in quantum field theory.

Relativistic Dynamics: The Speed of Light Limit

Explores relativistic dynamics and the unbreakable limit of the speed of light.

Particle Scattering: Relativistic Rutherford Cross Section

Explores the relativistic Rutherford cross section, Form Factor, quantum field theory, particle accelerators, and LHC production cross sections.

Quantum Mechanics: Non-Relativistic Qu

Explores the applicability of non-relativistic quantum mechanics and its relation to special relativity.

Gravitational Effects: Action Evaluation and Wavelength Shifts

Covers exercises on action evaluation, wavelength shifts, GPS accuracy, and the equivalence principle in gravitational fields.

Einstein's Equations: Relativistic Mechanics

Covers Einstein's equations in non-relativistic limit and the Schwarzschild metric.

Cosmological Puzzles: Dark Matter and Energy

Explores fundamental cosmological puzzles related to dark matter and energy.

Quantum Mechanics: Derivation and Logical Inference

Explores demystifying quantum mechanics through logical inference and robust experimental descriptions, emphasizing the separation of conditions and fundamental quantum equations.

Relativistic Quantum Mechanics

Introduces relativity into quantum mechanics and discusses the Dirac equation and 4x4 matrices.

Photon: Introduction and Properties

Covers the introduction and properties of photons, including their discovery and the Compton effect.

Elastic Scattering: Interactions of Electrons with Matter

Covers elastic scattering of fast electrons and their interactions with matter, including the derivation of the Mott formula and effective refractive index.