Vacancy-induced spin textures and their interactions in a classical spin liquid

Abstract

Motivated by experiments on the archetypal frustrated magnet SrCr9pGa12-9pO19 (SCGO), we study the classical Heisenberg model on the pyrochlore slab (Kagom\'e bilayer) lattice with site-dilution x=1-p. This allows us to address generic aspects of the physics of non-magnetic vacancies in a classical spin liquid. We explicitly demonstrate that the pure (x=0) system remains a spin-liquid down to the lowest temperatures, with an unusual non-monotonic temperature dependence of the susceptibility, which even turns diamagnetic for the apical spins between the two kagome layers. For x> 0 but small, the low temperature magnetic response of the system is most naturally described in terms of the properties of spatially extended spin textures that cloak an "orphan" S=3/2 Cr3+ spin in direct proximity to a pair of missing sites belonging to the same triangular simplex. In the T → 0 limit, these orphan-texture complexes each carry a net magnetization that is exactly half the magnetic moment of an individual spin of the undiluted system. Furthermore, we demonstrate that they interact via an entropic temperature dependent pair-wise exchange interaction Jeff(T,r) T J (r T) that has a logarithmic form at short-distances and decays exponentially beyond a thermal correlation length (T) 1/T. The sign of Jeff depends on whether the two orphan spins belong to the same Kagome layer or not. We provide a detailed analytical account of these properties using an effective field theory approach specifically tailored for the problem at hand. These results are in quantitative agreement with large-scale Monte Carlo numerics.