Robust spin liquid state against magnetic-dilution in the bi-layer Kagome material Ca10Cr7O28

Abstract

Recently, the bi-layer Kagome lattice material Ca10Cr7O28 has been shown to be a quasi-two-dimensional quantum spin liquid (QSL) where the frustration arises from a balance between competing ferromagnetic and antiferromagnetic exchange within a bi-layer. In an attempt to understand what happens when this balance is disturbed, we present a magnetic dilution study. Specifically, we have synthesized Ca10(Cr1-xVx)7O28 (0 ≤ x ≤ 0.5) where magnetic Cr5+ (S = 1/2) is partially replaced by non-magnetic V5+ (S = 0). We also synthesized the fully non-magnetic isostructural material Ca10V7O27.5. We report a detailed structural, magnetic and heat capacity study on these materials. A monotonic increase in the unit cell parameters is found for the Ca10(Cr1-xVx)7O28 materials with increasing x. An order of magnitude decrease in the Curie-Weiss temperature from 4 to 0.5~ K is found for the partial V substituted samples, which indicates a relative increase in antiferromagnetic exchange with increase in V content. However, despite this change in the relative balance in the exchange interactions and the large disorder introduced, no magnetic ordering or spin-glass state is observed down to 2~K in the V substituted samples. The QSL state of the parent compound thus seems surprisingly robust against these large perturbations.