String theories as the adiabatic limit of Yang-Mills theory

TL;DR

This paper demonstrates how string theories, including the Green-Schwarz superstring, can be derived as limits of Yang-Mills theory on specific manifolds, revealing a deep connection between gauge theories and string models.

Contribution

It shows that in the adiabatic limit, Yang-Mills equations on certain manifolds reduce to string equations in the loop group, extending previous results to include superstrings and different geometries.

Findings

String equations emerge from Yang-Mills in the adiabatic limit.

Green-Schwarz superstring action derived from Yang-Mills with a Wess-Zumino term.

String dynamics in flat spacetime obtained from gauge theory limits.

Abstract

We consider Yang-Mills theory with a matrix gauge group $G$ on a direct product manifold $M=\Sigma_2\times H^2$, where $\Sigma_2$ is a two-dimensional Lorentzian manifold and $H^2$ is a two-dimensional open disc with the boundary $S^1=\partial H^2$. The Euler-Lagrange equations for the metric on $\Sigma_2$ yield constraint equations for the Yang-Mills energy-momentum tensor. We show that in the adiabatic limit, when the metric on $H^2$ is scaled down, the Yang-Mills equations plus constraints on the energy-momentum tensor become the equations describing strings with a worldsheet $\Sigma_2$ moving in the based loop group $\Omega G=C^\infty (S^1, G)/G$, where $S^1$ is the boundary of $H^2$. By choosing $G=R^{d-1, 1}$ and putting to zero all parameters in $\Omega R^{d-1, 1}$ besides $R^{d-1, 1}$, we get a string moving in $R^{d-1, 1}$. In arXiv:1506.02175 it was described how one can obtain the Green-Schwarz superstring action from Yang-Mills theory on $\Sigma_2\times H^2$ while $H^2$ shrinks to a point. Here we also consider Yang-Mills theory on a three-dimensional manifold $\Sigma_2\times S^1$ and show that in the limit when the radius of $S^1$ tends to zero, the Yang-Mills action functional supplemented by a Wess-Zumino-type term becomes the Green-Schwarz superstring action.