Magnetic dilution and domain selection in the XY pyrochlore antiferromagnet Er2Ti2O7

Abstract

Below TN = 1.1K, the XY pyrochlore Er2Ti2O7 orders into a k=0 non-collinear, antiferromagnetic structure referred to as the 2 state. The magnetic order in Er2Ti2O7 is known to obey conventional three dimensional (3D) percolation in the presence of magnetic dilution, and in that sense is robust to disorder. Recently, however, two theoretical studies have predicted that the 2 structure should be unstable to the formation of a related 3 magnetic structure in the presence of magnetic vacancies. To investigate these theories, we have carried out systematic elastic and inelastic neutron scattering studies of three single crystals of Er2-xYxTi2O7 with x=0 (pure), 0.2 (10\%-Y) and 0.4 (20\%-Y), where magnetic Er3+ is substituted by non-magnetic Y3+. We find that the 2 ground state of pure Er2Ti2O7 is significantly affected by magnetic dilution. The characteristic domain selection associated with the 2 state, and the corresponding energy gap separating 2 from 3, vanish for Y3+ substitutions between 10\%-Y and 20\%-Y, far removed from the 3D percolation threshold of 60\%-Y. The resulting ground state for Er2Ti2O7 with magnetic dilutions from 20\%-Y up to the percolation threshold is naturally interpreted as a frozen mosaic of 2 and 3 domains.