High pressure sequence of Ba3NiSb2O9 structural phases: new S = 1 quantum spin-liquids based on Ni2+

Abstract

By using a high pressure, high temperature (HPHT) technique, the antiferromagnetically ordered (TN = 13.5 K) 6H-A phase of Ba3NiSb2O9 was transformed into two new gapless quantum spin liquid(QSL) candidates with S=1 (Ni2+) moments: the 6H-B phase with a Ni2+-triangular lattice and the 3C-phase with a Ni2+-three-dimensional (3D) edge-shared tetrahedral lattice. Both compounds show no magnetic order down to 0.35 K despite Curie-Weiss temperatures θCW of -75.5 K (6H-B) and -182.5 K (3C), respectively. Below 25 K the magnetic susceptibility of the 6H-B phase saturates to a constant value 0 = 0.013 emu/mol which is followed below 7 K, by a linear-temperature dependent magnetic specific heat (CM) displaying a giant coefficient γ = 168 mJ/mol-K2. Both observations suggest the development of a Fermi-liquid like ground state characterized by a Wilson ratio of 5.6 in this insulating material. For the 3C phase, the CM T2 behavior indicates a unique S=1, 3D QSL ground-state.