Thermodynamics and heat transport of quantum spin liquid candidates NaYbS2 and NaYbSe2
Abstract
We study the ultralow-temperature thermodynamics and thermal conductivity () of the single-crystal rare-earth chalcogenides NaYbS2 and NaYbSe2, which have an ideal triangular lattice of the Yb3+ ions and have been proposed to be quantum spin liquid candidates. The magnetic specific heat divided by temperature Cmag/T is nearly constant at T < 200 mK, which is indeed the indication of the gapless magnetic excitations with a constant density of states. However, we observe a vanishingly small residual term 0/T, which points to the absence of mobile fermionic excitations in these materials. Both the weak temperature dependence of and the strong magnetic-field dependence of suggest the significant scattering between the spinons and phonons, which actually supports the existence of gapless or tiny-gapped quantum spin liquid. Moreover, the (B)/(0) isotherms show a series of field-induced magnetic transitions for B a, confirming the easy-plane anisotropy, which is consistent with the results of ac magnetic susceptibility. We expect our results to inspire further interests in the understanding of the spinon-phonon coupling in the spin liquid systems.
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