Possible gapless spin liquid in a rare-earth kagom\'e lattice magnet Tm3Sb3Zn2O14

Abstract

We report the thermodynamic and muon spin relaxation (μSR) evidences for a possible gapless spin liquid in Tm3Sb3Zn2O14, with the rare-earth ions Tm3+ forming a two-dimensional kagom\'e lattice. We extract the magnetic specific heat of Tm3Sb3Zn2O14 by subtracting the phonon contribution of the non-magnetic isostructural material La3Sb3Zn2O14. We obtain a clear linear-T temperature dependence of magnetic specific heat at low temperatures, with the heat-capacity coefficient γ = 26.6(1) mJ mol-Tm-1 K-2 in the zero temperature limit. No long-range magnetic order was observed down to 0.35 K in the heat capacity measurement. A broad hump around 9 K was observed in the zero field magnetic specific heat and is gradually suppressed in the magnetic fields that also create a spin gap in the specific heat. The absence of magnetic order is further confirmed by the μSR measurement down to 20 mK. We find that the spin-lattice relaxation time remains constant down to the lowest temperatures. We point out that the physics in Tm3Sb3Zn2O14 is fundamentally different from the Cu-based herbertsmithite and propose spin liquid ground states with non-Kramers doublets on the kagom\'e lattice to account for the experimental results.