Absence of magnetic order and emergence of unconventional fluctuations in J eff =1/2 triangular lattice antiferromagnet YbBO3

Abstract

We present the ground state properties of a new quantum antiferromagnet YbBO3 in which the isotropic Yb3+ triangular layers are separated by a non-magnetic layer of partially occupied B and O(2) sites. The magnetization and heat capacity data establish a spin-orbit entangled effective spin J eff = 1/2 state of Yb3+ ions at low temperatures, interacting antiferromagnetically with an intra-layer coupling J/k B 0.53 K. The absence of oscillations and a 1/3 tail in the zero-field muon asymmetries rule out the onset of magnetic long-range-order as well as spin-freezing down to 20~mK. An anomalous broad maximum in the temperature dependent heat capacity with a unusually reduced value and a broad anomaly in zero-field muon depolarization rate centered at T* 0.7 Jk B provide compelling evidence for a wide fluctuating regime (0.182 ≤ T/J ≤ 1.63) with slow relaxation. We infer that the fluctuating regime is a universal feature of a highly frustrated triangular lattice antiferromagnets while the absence of magnetic long-range-order is due to perfect two-dimensionality of the spin-lattice protected by non-magnetic site disorder.