Magnetic ground state of a Jeff = 1/2 based frustrated triangular lattice antiferromagnet

Abstract: The subtle interplay between competing degrees of freedom, crystal electric fields, and spin correlations can lead to exotic quantum states in 4f ion-based frustrated magnets. We present the crystal structure, thermodynamic, and muon spin relaxation studies of the 4f ion-based frustrated magnet Ba4YbReWO12, wherein Yb3+ ions constitute a triangular lattice. The magnetic susceptibility does not show any signature of spin freezing down to 1.9 K or long-range magnetic ordering down to 0.4 K. The low-temperature Curie-Weiss fit to the inverse magnetic susceptibility data reveals a weak antiferromagnetic exchange interaction between the Jeff=1/2 state of the Yb3+ moments in the lowest Kramers doublet. The lowest Kramers ground state doublet is well separated from the first excited state with a gap of 278 K, as evidenced by our muon spin relaxation experiments that support the realization of the Jeff 1/2 state at low temperatures. The specific heat indicates a phase transition at 0.09 K, and the associated entropy release at low temperatures is consistent with that expected for the Jeff = 1/2 state. The zero-field muSR measurements show neither the signature of spin freezing nor a phase transition, at least down to 43 mK. Our results suggest the coexistence of static and slowly fluctuating moments in the ground state of this Jeff = 1/2 frustrated triangular lattice antiferromagnet. Ba4RReWO12 (R=rare earth) offers a viable platform to realize intriguing quantum states borne out of spin-orbit coupling and frustration.