Topological Insulators Avoid the Parity Anomaly
Abstract
The surface of a 3+1d topological insulator hosts an odd number of gapless Dirac fermions when charge conjugation and time-reversal symmetries are preserved. Viewed as a purely 2+1d system, this surface theory would necessarily explicitly break parity and time-reversal when coupled to a fluctuating gauge field. Here we explain why such a state can exist on the boundary of a 3+1d system without breaking these symmetries, even if the number of boundary components is odd. This is accomplished from two complementary perspectives: topological quantization conditions and regularization. We first discuss the conditions under which (continuous) large gauge transformations may exist when the theory lives on a boundary of a higher-dimensional spacetime. Next, we show how the higher-dimensional bulk theory is essential in providing a parity-invariant regularization of the theory living on the lower-dimensional boundary or defect.
Cite
@article{arxiv.1301.4230,
title = {Topological Insulators Avoid the Parity Anomaly},
author = {Michael Mulligan and F. J. Burnell},
journal= {arXiv preprint arXiv:1301.4230},
year = {2013}
}
Comments
46 pages, 1 figure, harvmac