The frustrated Heisenberg antiferromagnet on the checkerboard lattice: the J1--J2 model

Abstract

We study the ground-state (gs) phases of the spin-half anisotropic planar pyrochlore (or crossed chain) model using the coupled cluster method (CCM). The model is a frustrated antiferromagnetic (AFM) J1--J2 system on the checkerboard lattice, with nearest-neighbor exchange bonds J1>0 and next-nearest-neighbor bonds J2 J1 > 0. Using various AFM classical ground states as CCM model states we present results for their gs energy, average on-site magnetization, and susceptibilities to plaquette valence-bond crystal (PVBC) and crossed-dimer valence-bond crystal (CDVBC) ordering. We show that the state with Neel ordering is the gs phase for < c1 ≈ 0.80 0.01, but that none of the fourfold set of AFM states selected by quantum fluctuations at O(1/s) in a large-s analysis (where s is the spin quantum number) from the infinitely degenerate set of AFM states that form the gs phase for the classical version of the model (for >1) survives the quantum fluctuations to form a stable magnetically-ordered gs phase for the spin-half case. The Neel state becomes susceptible to PVBC ordering at or very near to = c1, and the fourfold AFM states become infinitely susceptible to PVBC ordering at = c2 ≈ 1.22 0.02. In turn, we find that these states become infinitely susceptible to CDVBC ordering for all values of above a certain critical value at or very near to = c2. We thus find a Neel-ordered gs phase for <c1, a PVBC-ordered phase for c1 < < c2, and a CDVBC-ordered phase for > c2. Both transitions are probably direct ones, although we cannot exclude very narrow coexistence regions confined to 0.79 0.81 and 1.20 1.22 respectively.