Dimensional reduction in superconducting arrays and frustrated magnets
Abstract
Some frustrated magnets and superconducting arrays possess unusual symmetries that cause the free energy or other physics of a D-dimensional quantum or classical problem to be that of a different problem in a reduced dimension d<D. Examples in two spatial dimensions include the square-lattice p+ip superconducting array, the Heisenberg antiferromagnet on the checkerboard lattice (studied by a combination of 1/S expansion and numerical transfer matrix), and the ring-exchange superconducting array. Physical consequences are discussed both for ``weak'' dimensional reduction, which appears only in the ground state degeneracy, and ``strong'' dimensional reduction, which applies throughout the phase diagram. The ``strong'' dimensional reduction cases have the full lattice symmetry and do not decouple into independent chains, but their phase diagrams, self-dualities, and correlation functions indicate a reduced effective dimensionality. We find a general phase diagram for quantum dimensional reduction models in two quantum dimensions with N-fold anisotropy, and obtain the Kosterlitz-Thouless-like phase transition as a deconfinement of dipoles of 3D solitons.
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