Module #1 Introduction to Particle Physics Overview of the standard model, fundamental forces, and particles
Module #2 Review of Quantum Mechanics Revision of key concepts in quantum mechanics, including wave functions, operators, and spinors
Module #3 Classical Field Theory Introduction to classical field theory, including Lagrangians and Euler-Lagrange equations
Module #4 Quantization of Fields Introduction to quantization of fields, including canonical quantization and path integrals
Module #5 Free Fields and Their Properties Properties of free fields, including scalar, spinor, and vector fields
Module #6 Interacting Fields and Feynman Rules Introduction to interacting fields, including Feynman diagrams and rules for scalar, spinor, and vector fields
Module #7 Renormalization Introduction to renormalization, including regularization and counterterms
Module #8 Symmetries in Quantum Field Theory Introduction to symmetries in QFT, including internal and space-time symmetries
Module #9 Noethers Theorem and Currents Application of Noethers theorem to derive conserved currents
Module #10 Spontaneous Symmetry Breaking Introduction to spontaneous symmetry breaking, including the Goldstone theorem
Module #11 The Electroweak Force Electroweak unification, including the Higgs mechanism and gauge bosons
Module #12 Quantum Electrodynamics (QED) Introduction to QED, including Feynman rules and renormalization
Module #13 Quantum Chromodynamics (QCD) Introduction to QCD, including asymptotic freedom and confinement
Module #14 Hadronic Physics Introduction to hadronic physics, including quark models and hadron spectroscopy
Module #15 Beyond the Standard Model Introduction to beyond the Standard Model physics, including supersymmetry and extra dimensions
Module #16 Flavor Physics Introduction to flavor physics, including CKM matrix and neutrino oscillations
Module #17 Neutrino Physics Introduction to neutrino physics, including neutrino oscillations and mass models
Module #18 Dark Matter and Dark Energy Introduction to dark matter and dark energy, including theoretical models and experimental searches
Module #19 Cosmology and the Early Universe Introduction to cosmology, including the Big Bang theory and cosmic microwave background radiation
Module #20 Lattice Field Theory Introduction to lattice field theory, including numerical simulations and results
Module #21 Effective Field Theories Introduction to effective field theories, including chiral perturbation theory and heavy quark effective theory
Module #22 Scattering and Decay Processes Introduction to scattering and decay processes, including cross-section calculations and kinematics
Module #23 Particle Detectors and Experimental Methods Introduction to particle detectors and experimental methods, including tracking, calorimetry, and trigger systems
Module #24 Computational Tools for QFT Introduction to computational tools for QFT, including FeynArts, FormCalc, and MadGraph
Module #25 Course Wrap-Up & Conclusion Planning next steps in Quantum Field Theory and Particle Physics career
