Gapless triangular-lattice spin-liquid candidate PrZnAl11O19

A quantum spin liquid (QSL) is an exotic state in which electron spins are highly entangled, yet keep fluctuating even at zero temperature. Experimental realization of model QSLs has been challenging due to imperfections, such as antisite disorder, strain, and extra or a lack of interactions in real materials compared to the model Hamiltonian. Here we report the magnetic susceptibility, thermodynamic, inelastic neutron scattering (INS), and muon-spin relaxation studies on a polycrystalline sample of PrZnAl11O19, where the Pr3+ ions form an ideal two-dimensional triangular lattice. Our results demonstrate that this system does not order nor freeze, but keeps fluctuating down to 50 mK despite large antiferromagnetic couplings (similar to - 10 K). Furthermore, the INS and specific-heat data suggest that PrZnAl11O19 is best described as a gapless QSL.

Automated summary

This study presents magnetic susceptibility, thermodynamic, inelastic neutron scattering, and muon-spin relaxation studies on a polycrystalline sample of PrZnAl11O19. The results demonstrate that despite large antiferromagnetic couplings, this system continues to fluctuate at low temperatures and can be described as a gapless quantum spin liquid.