Thermal Conductivity due to Spins in the Two-Dimensional Spin System Ba2Cu3O4Cl2
Abstract
We have measured the temperature dependences of the thermal conductivity of Ba2Cu3-xMxO4Cl2 (M = Pd, Ni, Co; x = 0, 0.03) single crystals including two-dimensional (2D) Cu3O4 planes consisting of a strong 2D spin network of CuA2+ spins and a weak 2D spin network of CuB2+ spins. It has been found that the thermal conductivity due to spins, spin, exists in the thermal conductivity parallel to the Cu3O4 plane owing to the strong 2D spin network of CuA2+ spins and exhibits a broad peak around room temperature. The maximum value of spin is ~7 W/Km and comparable with that in Nd2CuO4 with almost the same 2D spin network of Cu2+ spins. The spin has been found to be suppressed by 1% impurities on account the decrease in the mean free path of magnetic excitations, suggesting that spin is expected to be enhanced in 2D quantum spin systems such as Ba2Cu3O4Cl2 by reducing the amount of impurities in a single crystal. Moreover, it has concluded that the frustration between CuA2+ and CuB2+ spins little affects the existence of spin.
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