The quantum theory of fields

Supersymmetry is an idea that has played a critical role in many of the recent developments in theoretical physics of interest to mathematicians. The third volume of The quantum theory of fields by Steven Weinberg [1] is an introduction to supersymmetric field theory and supergravity. The first two volumes of the series treat the essentials of quantum field theory. In this third volume, Weinberg has created the most complete introduction to supersymmetry to date. Although the text is aimed squarely at physicists, it should prove useful to mathematicians interested in learning about supersymmetry in its natural physical setting. As a supplement, to help bridge the cultural and language differences between physics and mathematics, I would suggest the short lecture series by Freed [2]. My goal, in the course of this review, is to convey both the essential idea behind supersymmetry and some of the background needed to peruse the physics literature. What is supersymmetry? The basic notion behind supersymmetry (SUSY) can be described in the setting of quantum mechanics. As a starting point, let us consider a particle in one dimension with position x moving in a potential well, V (x). The time evolution of this system is governed by a Hamiltonian, H , which takes the form