Relativistic Quantum Field Theory I
About Course
An expert-level course from MIT OpenCourseWare on Relativistic Quantum Field Theory, covering classical fields, canonical quantization, path integrals, and QED.
Course Content
Relativistic Quantum Field Theory I
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Lecture 1: Classical Field Theories and Principle of Locality
01:09:09 -
Lecture 2: Symmetries and Conservation Laws
01:21:32 -
Lecture 3: Why Quantum Field Theory
01:14:53 -
Lecture 4: Canonical Quantization of a Free Scalar Field Theory
01:18:31 -
Lecture 5: Complex Scalar Field Theory and Anti-Particle
01:19:42 -
Lecture 6: Propagators and Green Functions
01:21:09 -
Lecture 7: Interacting Theories and S-Matrix
01:04:32 -
Lecture 8: Path Integral Formalism for Non-Relativistic Quantum Mechanics
01:22:45 -
Lecture 9: Path Integral Formalism for QFT; Computation of Time-Ordered Correlation Functions
01:19:48 -
Lecture 10: Time-Ordered Correlation Functions in Field Theory
01:21:44 -
Lecture 11: Computation of Correlation Functions in Perturbation Theory and Feynman Diagrams
01:20:06 -
Lecture 12: More on Perturbation Theory and Feynman Diagrams
01:20:11 -
Lecture 13: Introducing the Dirac Equation
01:20:12 -
Lecture 14: Lorentz Covariance of the Dirac Equation
01:18:26 -
Lecture 15: Classical Solutions of Dirac Equations
01:20:47 -
Lecture 16: Quantization of the Dirac Theory
01:18:06 -
Lecture 17: Chiral and Majorana Spinors
01:20:23 -
Lecture 18: Discrete Symmetries
01:19:43 -
Lecture 19: Path Integrals of Fermions
01:21:55 -
Lecture 20: Maxwell Theory and its Canonical Quantization
01:19:20 -
Lecture 21: Quantum Maxwell Theory (continued )
01:16:41 -
Lecture 22: Quantum Electrodynamics
01:17:30 -
Lecture 23: Cross Section and Decay Rate
01:20:01 -
Lecture 24: Elementary Processes in QED (I )
01:18:16 -
Lecture 25: Elementary Processes in QED (II )
01:21:12 -
Lecture 26: Quantum Fluctuations and Renormalization
01:21:45
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