Ground states of the infinite q-deformed Heisenberg ferromagnet
Abstract
We set up a general structure for the analysis of ``frustration-free ground states'', or ``zero-energy states'', i.e., states minimizing each term in a lattice interaction individually. The nesting of the finite volume ground state spaces is described by a generalized inductive limit of observable algebras. The limit space of this inductive system has a state space which is canonically isomorphic (as a compact convex set) to the set of zero-energy states. We show that for Heisenberg ferromagnets, and for generalized valence bond solid states, the limit space is an abelian C*-algebra, and all zero-energy states are translationally invariant or periodic. For the q-deformed spin-1/2 Heisenberg ferromagnet in one dimension (i.e., the XXZ-chain with SqU(2)-invariant boundary conditions) the limit space is an extension of the non-commutative algebra of compact operators by two points, corresponding to the ``all spins up'' and the ``all spins down'' states, respectively. These are the only translationally invariant zero-energy states. The remaining ones are parametrized by the density matrices on a Hilbert space, and converge weakly to the ``all up'' (resp.\ ``all down'') state for shifts to -∞ (resp.\ +∞).
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