Instabilities of the Hubbard chain in a magnetic field
Abstract
We find and characterize the instabilities of the repulsive Hubbard chain in a magnetic field by studing all response functions at low frequency ω and arbitrary momentum. The instabilities occur at momenta which are simple combinations of the (U=0) σ = , Fermi points, kFσ. For finite values of the on-site repulsion U the instabilities occur for single σ electron adding or removing at momenta kFσ, for transverse spin-density wave (SDW) at momenta 2kF (where 2kF=kF+kF), and for charge-density wave (CDW) and SDW at momenta 2kF and 2kF. While at zero magnetic field removing or adding single electrons is dominant, the presence of that field brings about a dominance for the transverse 2kF SDW over all the remaining instabilities for a large domain of U and density n values. We go beyond conformal-field theory and study divergences which occur at finite frequency in the one-electron Green function at half filling and in the transverse-spin response function in the fully-polarized ferromagnetic phase.
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