Introduction to Field Theory Lecture by Ronald Kleiss (University of Nijmegen, NL) CERN, Geneva      Summary: Starting from the notion of path integrals as developed by Feynman, we discuss field theory in zero spacetime dimensions. The concepts of perturbation expansions, connected amplitudes, Feynman diagrams, classical solutions, renormalization and the effective action are developed. The model is extended to four spacetime dimensions, and the full Feynman rules for relativisitc scalar theory derived. The S matrix and the concept of unitarity are discussed, leading to the amputation rules for S matrix elements from considerations of unitarity. The rules are extended to include particles with spin-1/2 and spin-1. The high-energy behaviour of the theory is discussed as a method to derive the gauge symmetry of the various models. Lecture number Title RealPlayer Plug-in RealPlayer Detached [1/10] Introduction to Field Theory - Lecture 1    no slides no slides [2/10] Introduction to Field Theory - Lecture 2    [3/10] Introduction to Field Theory - Lecture 3    [4/10] Introduction to Field Theory - Lecture 4    [5/10] Introduction to Field Theory - Lecture 5    [6/10] Introduction to Field Theory - Lecture 6    [7/10] Introduction to Field Theory - Lecture 7    [8/10] Introduction to Field Theory - Lecture 8    [9/10] Introduction to Field Theory - Lecture 9    [10/10] Introduction to Field Theory - Lecture 10    Additional Notes: Notes in PostScript format are also available (right-click to download). This document and others can be found at Professor Kleiss' home page For information: wlap@umich.edu Last modified: Wednesday, 16-Jul-2003 18:39:55 EDT