Lectures related to Quantum Field Theory I: Introduction to Relativistic Quantum Field Theory

Overview of Particle Physics and Rutherford Scattering

Covers the constituents of matter, fundamental forces, the Standard Model, natural units, and particle interaction experiments.

Particle Physics: Standard Model overview

Covers Particle Physics, elementary particles, fundamental forces, the Standard Model, and precision physics in late 20th-century physics.

The Higgs Mechanism

Explores the formal aspects of the Higgs mechanism, covering mass terms, symmetry breaking, and the standard model Higgs boson.

The Higgs Mechanism: Formal Aspects

Covers the formal aspects of the Higgs mechanism, explaining mass terms for scalar and gauge bosons through symmetry breaking.

Simulating the Early Universe: Techniques and Challenges

Covers numerical techniques for simulating the early universe, focusing on gauge invariance and fermions.

Asymptotic States and S-matrix: Operators

Explores asymptotic states, S-matrix, and operators in quantum field theory, emphasizing the role of discrete symmetries and complete sets of states.

Goldstone Bosons: Higgs Mechanism

Explores Goldstone bosons and the Higgs mechanism, revealing how spontaneous symmetry breaking generates mass for gauge bosons.

Gauge Theories And Modern Particle Physics

Covers gauge theories, modern particle physics, the standard model, and field content.

Quantum Field Theory: Behind and Beyond the Standard Model

Delves into quantum field theory, emphasizing the Standard Model's boundaries and the principles governing particle physics.

Particle Physics: Fundamentals and Interactions

Covers the basics of particle physics, including elementary particles, forces, the Standard Model, and rare phenomena at the LHC.

Quantum Field Theory: Fundamentals and Applications

Introduces Quantum Field Theory, covering paths to QFT, fields, weak interactions, and the Standard Model of particle Physics.

Discrete Symmetries Introduction

Introduces the concept of discrete symmetries in Quantum Field Theory and their impact on particles and anti-particles.

Pseudonambulgol from Bosons: Methane and Effective Field Theory

Explores the relationship between methane and effective field theory, focusing on the impact of multi-poles on the electrostatic potential between molecules.

The Higgs Mechanism: Unveiling Mass Generation

Explores the Higgs mechanism, solving the issue of massless gauge bosons and predicting masses of gauge bosons.

Quantum Field Theory II: Gauge Theories

Explores Quantum Field Theory II, emphasizing Gauge Theories, including QED, fermion masses, vector bosons, and the Higgs mechanism.

Probability and Statistics for Physics

Introduces probability and statistics concepts in physics, exploring the Standard Model and practical applications.

Particle Physics: Symmetry and Conservation Laws

Explores particle physics, focusing on symmetry and conservation laws in physics.

Time Reversal Symmetry

Explores time reversal symmetry, invariance under parity, eigenstates, and spin in quantum physics.

Global Conservation Laws

Explores the dynamical consequences of symmetry, emphasizing conservation laws and the role of Noether currents.

Advanced Physics: Energy Conservation

Covers rotation, collisions, and energy conservation in advanced physics.