Unusual heat transport of the Kitaev material Na2Co2TeO6: putative quantum spin liquid and low-energy spin excitations
Abstract
We studied the field dependent thermal conductivity () of Na2Co2TeO6, a compound considered as the manifestation of the Kitaev model based on the high-spin d7 Co2+ ions. We found that in-plane magnetic fields beyond a critical value Bc ≈~10 T are able to drastically enhance at low temperatures, resulting in a double-peak structure of (T) that closely resembles the behavior of α-RuCl3. This result suggests that heat transport in Na2Co2TeO6 is primarily phononic, and it is strongly affected by scattering from magnetic excitations that are highly tunable by external fields. Interestingly, for magnetic fields B // a (i.e., along the zigzag direction of the Co-Co bonds), there is an extended field range which separates the long-range magnetic order for B≤ Bc≈10 T and the partially spin-polarized gapped high-field phase for B 12 T. The low-energy phonon scattering is particularly strong in this field range, consistent with the notion that the system becomes a quantum spin liquid with prominent spin fluctuations down to energies of no more than 2 meV.
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