We consider the effects of Coulomb interactions on single-wall carbon
nanotubes using an on-site Hubbard interaction, u. For the (N,N) armch
air tubes the low-energy theory is shown to be identical to a two-chai
n Hubbard model at half-filling, with an effective interaction U-N=u/N
. Umklapp scattering leads to gaps in the spectrum of charge and spin
excitations which are exponentially small for large N. Above the gaps
the intrinsic nanotube resistivity due to these scattering processes i
s linear in temperature, as observed experimentally. The presence of '
'd-wave'' superconductivity in the two-chain Hubbard model away from h
alf-filling suggests that doped armchair nanotubes might exhibit super
conductivity with a purely electronic mechanism.