Supersymmetric Quantum Mechanics and Path Integrals

TL;DR

This paper reviews supersymmetric quantum mechanics, emphasizing the role of instantons and path integrals in understanding supersymmetry breaking, and highlights limitations of perturbation theory in this context.

Contribution

It introduces methods using instantons and path integrals to analyze supersymmetry breaking beyond perturbation theory in quantum mechanics.

Findings

Instantons contribute to tunneling effects in quantum mechanics.

Perturbation theory fails to explain supersymmetry breaking.

Non-perturbative effects can induce supersymmetry breaking.

Abstract

Supersymmetry plays a main role in all current thinking about superstring theory. Indeed, many remarkable properties of string theory have been explained using supersymmetry as a tool. In this dissertation, we review the basic formulation of supersymmetric quantum mechanics starting with introducing the concepts of supercharges and superalgebra. We show that, if there is a supersymmetric state, it is the zero-energy ground state. If such a state exists, the supersymmetry is unbroken otherwise it is broken. So far, there has been no unbroken supersymmetry observed in nature, and if nature is described by supersymmetry, it must be broken. In fact, supersymmetry may be broken spontaneously at any order of perturbation theory, or dynamically due to non-perturbative effects. The goal of this dissertation is to study the methods of supersymmetry breaking. For this purpose, special attention is given to discuss the normalization of the ground state of the supersymmetric harmonic oscillator. Then we explain that perturbation theory gives us incorrect results for both the ground state wave function as well as the energy spectrum and it fails to give an explanation to the supersymmetry breaking. Later in the dissertation, a review of the uses of instantons in quantum mechanics is given. In particular, instantons are used to compute the tunneling effects within the path integral approach to quantum mechanics. As a result, we give evidence that the instantons, which are a non-perturbative effect in quantum mechanics and can not be seen in perturbation theory, leads to calculate the corrections to the ground state energy and provides a possible explanation for the supersymmetry breaking.