Recently there has been considerable interest in the properties of carbon
nanotori. Such nanotori can be parametrized according to their radii, their
chiralities, and the twists that occur upon joining opposite ends of the
nanotubes from which they are derived. In this paper, however, we demonstrate
that many physically distinct nanotori with wildly different parameters
nevertheless share identical band structures, energy spectra, and electrical
conductivities. This occurs as a result of certain geometric symmetries known
as modular symmetries which are direct consequences of the properties of the
compactified graphene sheet. Using these symmetries, we show that there is a
dramatic reduction in the number of spectrally distinct carbon nanotori
compared with the number of physically distinct carbon nanotori. The existence
of these modular symmetries also allows us to demonstrate that many statements
in the literature concerning the electronic properties of nanotori are
incomplete because they fail to respect the spectral equivalences that follow
from these symmetries. We also find that as a result of these modular
symmetries, the fraction of spectrally distinct nanotori which are metallic is
approximately three times greater than would naively be expected on the basis
of standard results in the literature. Finally, we demonstrate that these
modular symmetries also extend to cases in which our carbon nanotori enclose
non-zero magnetic fluxes.Comment: 12 pages, ReVTeX, 6 figures, 1 table. Replaced to match published
versio