Proximate quantum spin liquid state in the frustrated HoInCu4 metal

Abstract

We conducted a comprehensive and comparative muon-spin relaxation and rotation (μSR) investigation on two fcc-lattice metallic compounds, HoCdCu4 (TN≈ 8 K) and HoInCu4 (TN≈ 0.76 K), to elucidate the nature of their magnetic ground states and the role of frustration in stabilizing them. Our μSR results reveal that, in contrast to HoCdCu4, strong magnetic frustration exists in HoInCu4. Notably, in HoInCu4, only 30% of the Ho-moments participate in the static magnetic ordering below TN, while the remaining 70% of the Ho-moments exhibit dynamic correlations and persistent spin dynamics down to 0.3 K, resembling a quantum spin-liquid (QSL) behavior. By contrast, in HoCdCu4, all the Ho-moments contribute to the magnetic order below TN. Furthermore, in HoInCu4, the temperature dependence of the relaxation rate indicates the presence of quantum critical fluctuations in the paramagnetic state near TN, suggesting the proximity to a quantum critical point (QCP). These observations suggest that the ground state of HoInCu4 is a proximate quantum spin liquid (PQSL), a state that has not been reported before in frustrated metallic systems. Our μSR findings are further corroborated by recent inelastic neutron results on HoInCu4, which show similarities to other insulating PQSL candidates, thus reinforcing our conclusions.