Estimation of the charge carrier localization length from Gaussian fluctuations in the magneto-thermopower of La0.6Y0.1Ca0.3MnO3
Abstract
The magneto-thermoelectric power (TEP) S(T,H) of perovskite type manganise oxide La0.6Y0.1Ca0.3MnO3 is found to exhibit a sharp peak at some temperature T*=170K. By approximating the true shape of the measured magneto-TEP in the vicinity of T* by a linear triangle of the form S(T,H) Sp(H) B(H)(T*-T), we observe that B -(H) 2B +(H). We adopt the electron localization scenario and introduce a Ginzburg-Landau (GL) type theory which incorporates the two concurrent phase transitions, viz., the paramagnetic-ferromagnetic transition at the Curie point TC and the "metal-insulator" (M-I) transition at TMI. The latter is characterized by the divergence of the field-dependent charge carrier localization length (T,H) at some characteristic field H0. Calculating the average and fluctuation contributions to the total magnetization and the transport entropy related magneto-TEP S(T,H) within the GL theory, we obtain a simple relationship between T* and the above two critical temperatures (TC and TMI). The observed slope ratio B -(H)/B +(H) is found to be governed by the competition between the electron-spin exchange JS and the induced magnetic energy MsH0. The comparison of our data with the model predictions produce TC=195K, JS=40meV, M0=0.4Ms, 0=10, and ne/ni=2/3 for the estimates of the Curie temperature, the exchange coupling constant, the critical magnetization, the localization length, and the free-to-localized carrier number density ratio, respectively.
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