Magnetic dilution in the triangular lattice antiferromagnet NaYb1-xLuxO2

Abstract

The delafossite-like compound NaYbO2 hosts a triangular lattice of Yb3+ moments and is a promising candidate for the realization of a quantum spin liquid ground state -- an exotic, quantum-disordered magnetic phase featuring long-range entanglement of spins. Tuning this system away from this quantum-disordered regime toward classical order or spin freezing is a powerful approach to shed light on the nature of the parent ground state. Here we leverage the substitution of nonmagnetic Lu3+ onto the Yb3+ sites to study the effects of magnetic disorder in NaYbO2 using low-temperature ac susceptibility, heat capacity, and muon spin relaxation (μSR) measurements. Our μSR measurements reveal resilient, correlated magnetic fluctuations that persist to at least 15\% dilution, precluding conventional spin freezing and magnetic inhomogeneity. Heat capacity and magnetic susceptibility resolve a rapid suppression of the field-induced ``up-up-down'' magnetic order upon dilution and a crossover in the power-law behavior of the low-temperature magnetic excitations associated with the zero-field quantum disordered ground state. Taken together, these results support the notion of a robust network of entangled moments in NaYbO2, and provides experimental validation of several models of a Heisenberg triangular lattice antiferromagnet in the presence of disorder.