Evolution of magnetic, transport, and thermal properties in Na4-xIr3O8

Abstract

The hyper-kagome material Na4Ir3O8 is a three-dimensional spin-liquid candidate proximate to a quantum critical point (QCP). We present a comprehensive study of the structure, magnetic susceptibility , heat capacity C, and electrical transport on polycrystalline samples of the doped hyper-kagome material Na4-xIr3O8 (x ≈ 0, 0.1, 0.3, 0.7). Materials with x≤ 0.3 are found to be Mott insulators with strong antiferromagnetic interactions and no magnetic ordering down to T = 2 K\@. All samples show irreversibility below T ≈ 6 K between the zero-field-cooled and field-cooled magnetization measured in low fields (H = 0.050 T) suggesting a frozen low temperature state although no corresponding anomaly is seen in the heat capacity. The x = 0.7 sample shows (T) which weakly increases with decreasing temperature T, nearly T independent , a linear in T contribution to the low temperature C, and a Wilson ratio RW ≈ 7 suggesting anomalous semi-metallic behavior.