Scaling behaviour of magnetic entropy change in bilayered manganites by two-variable polynomials fitting to magnetization
Bao Xu

TL;DR
This paper investigates the scaling behavior of magnetic entropy change in bilayered manganites using a two-variable polynomial model, revealing differences from previous structures and field-dependent transition behaviors.
Contribution
It introduces a polynomial modeling approach to analyze magnetic entropy change and uncovers distinct scaling behaviors in bilayered manganites with 327-structure.
Findings
Curie temperature differs from peak magnetic entropy temperature
Scaling behavior varies between weak and strong magnetic fields
Crossover from one-step to two-step transition under increasing fields
Abstract
Based on the two-variable polynomial model of magnetization, magnetic entropy change of bilayered manganites with -structure and its scaling behaviour with respect to applied magnetic fields are investigated. It's found that the Curie temperature, which is defined as the point at which the partial derivative of magnetization with respect to temperature reaches its maximum, is different from the temperature of peak magnetic entropy change. Thus a mean-field model can not apply to this kind of manganites. In contrast to what has been found in manganites with the -structure, the scaling behaviour at the Curie temperature in manganites with -structure is much different from that at the temperature of peak magnetic entropy. It's also found that the temperature dependence of the scaling exponent under weak fields is distinct from that under strong fields.This difference is…
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Taxonomy
TopicsAdvanced Thermodynamics and Statistical Mechanics · Theoretical and Computational Physics · Magnetic and transport properties of perovskites and related materials
