Strange Metals in One Spatial Dimension
Abstract
We consider 1+1 dimensional SU(N) gauge theory coupled to a multiplet of massive Dirac fermions transforming in the adjoint representation of the gauge group. The only global symmetry of this theory is a U(1) associated with the conserved Dirac fermion number, and we study the theory at variable, non-zero densities. The high density limit is characterized by a deconfined Fermi surface state with Fermi wavevector equal to that of free gauge-charged fermions. Its low energy fluctuations are described by a coset conformal field theory with central charge c=(N^2-1)/3 and an emergent N=(2,2) supersymmetry: the U(1) fermion number symmetry becomes an R-symmetry. We determine the exact scaling dimensions of the operators associated with Friedel oscillations and pairing correlations. For N>2, we find that the symmetries allow relevant perturbations to this state. We discuss aspects of the N->infty limit, and its possible dual description in AdS3 involving string theory or higher-spin gauge theory. We also discuss the low density limit of the theory by computing the low lying bound state spectrum of the large N gauge theory numerically at zero density, using discretized light cone quantization.
Keywords
Cite
@article{arxiv.1206.4719,
title = {Strange Metals in One Spatial Dimension},
author = {Rajesh Gopakumar and Akikazu Hashimoto and Igor R. Klebanov and Subir Sachdev and Kareljan Schoutens},
journal= {arXiv preprint arXiv:1206.4719},
year = {2012}
}
Comments
40 pages, 4 figures