Magnon-polaron and Spin-polaron Signatures in the Specific Heat and Electrical Resistivity of La0.6Y0.1Ca0.3MnO3 in Zero Magnetic Field, and the Effect of Mn-O-Mn Bond Environment
Abstract
La0.6Y0.1Ca0.3MnO3, an ABO3 perovskite manganite oxide, exhibits a non trivial behavior in the vicinity of the sharp peak found in the resistivity as a function of temperature T in zero magnetic field. The various features seen on d/dT are discussed in terms of competing phase transitions. They are related to the Mn-O-Mn bond environment depending on the content of the A crystallographic site. A Ginzburg-Landau type theory is presented for incorporating concurrent phase transitions. The specific heat C of such a compound is also examined from 50 till 200 K. A log-log analysis indicates different regimes. In the low temperature conducting ferromagnetic phase, a collective magnon signature (C T3/2) is found as for what are called magnon-polaron excitations. A C T2/3 law is found at high temperature and discussed in terms of the fractal dimension of the conducting network of the weakly conducting (so-called insulating) phase and Orbach estimate of the excitation spectral behaviors. The need of considering both independent spin scattering and collective spin scattering is thus emphasized. The report indicates a remarkable agreement for the Fisher-Langer formula, i.e. C d/dT at second order phase transitions. Within the Attfield model, we find an inverse square root relationship between the critical temperature(s) and the total local Mn-O-Mn strain.
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