This study reports a large magneto-thermal conductivity effect in Ag2Te, which can be used in heat flow switches and thermoelectric devices at various temperatures, including room temperature. When a magnetic field of mu H-0 = 9 T is applied perpendicular to the heat and electric currents, the thermal conductivity of Ag2Te decreases by 61%. This effect is mainly due to the suppressed electronic thermal conductivity and magnetoresistance effect, resulting in a significant increase in the thermoelectric figure of merit.
In this study, we report a large magneto-thermal conductivity effect, potentially usable in heat flow switches and thermoelectric devices, in Ag2Te over a wide temperature range, including room temperature. When a magnetic field of mu H-0 = 9 T is applied to Ag2Te at 300 K along the direction perpendicular to the heat and electric currents, the thermal conductivity kappa decreases by a remarkable 61%. This effect is mainly caused by the suppressed electronic thermal conductivity in association with a significant magnetoresistance effect, but the suppression of the thermal conductivity is larger than that of the electrical conductivity, presumably due to a field-induced decrease in the Lorenz ratio. Its very low lattice thermal conductivity, as low as 0.5 W m(-1) K-1, also greatly contributes to the large relative magneto-thermal conductivity effect. The significant decrease in thermal conductivity and the 18% increase in the Seebeck coefficient S lead to a nearly 100% increase in the thermoelectric figure of merit zT = S-2 sigma T kappa(-1) despite the 43% decrease in electrical conductivity sigma.
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