Solving 2D QCD with an adjoint fermion analytically
Abstract
We present an analytic approach to solving 1+1 dimensional QCD with an adjoint Majorana fermion. In the UV this theory is described by a trivial CFT containing free fermions. The quasi-primary operators of this CFT lead to a discrete basis of states which is useful for diagonalizing the Hamiltonian of the full strongly interacting theory. Working at large-, we find that the decoupling of high scaling-dimension quasi-primary operators from the low-energy spectrum occurs exponentially fast in their scaling-dimension. This suggests a scheme, whereby, truncating the basis to operators of dimension below , one can calculate the low-energy spectrum, parametrically to an accuracy of (although the precise accuracy depends on the state). Choosing we find very good agreement with the known spectrum obtained earlier by numerical DLCQ methods. Specifically, below the first three-particle threshold, we are able to identify all six single-particle bound-states, as well as several two-particle thresholds.
Cite
@article{arxiv.1308.4980,
title = {Solving 2D QCD with an adjoint fermion analytically},
author = {Emanuel Katz and Gustavo Marques Tavares and Yiming Xu},
journal= {arXiv preprint arXiv:1308.4980},
year = {2015}
}
Comments
26 pages, 5 figures; v2: some typos corrected