Investigation of the Structural, Magnetic, Magnetocaloric, Electrical Properties, and Spin-Polarized Tunneling Effect of the La0.5Ca0.3Te0.2MnO3 System

Investigation of the Structural, Magnetic, Magnetocaloric, Electrical Properties, and Spin-Polarized Tunneling Effect of the La0.5Ca0.3Te0.2MnO3 System

Structural, magnetic, magnetocaloric, electrical properties, and spin-polarized tunneling effect in La 0.5 Ca 0.3 Te 0.2 MnO 3 polycrystalline were studied in details. The temperature dependence of the inverse of the magnetic susceptibility indicates the presence of ferromagnetic exchange interactio...

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Bibliographic Details
Published in:Journal of superconductivity and novel magnetism Vol. 32; no. 3; pp. 463 - 473
Main Authors: Felhi, H., Smari, M., Hamdi, R., Mnasri, T., Bekri, M., Dhahri, E.
Format: Journal Article
Language:English
Published: New York Springer US 01-03-2019
Subjects:
Characterization and Evaluation of Materials
Condensed Matter Physics
Magnetic Materials
Magnetism
Physics
Physics and Astronomy
Review Paper
Strongly Correlated Systems
Superconductivity
Perovskite manganite
Spin-polarized tunneling effect
Magnetocaloric effect
Resistivity
Magnetic properties
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Summary:Structural, magnetic, magnetocaloric, electrical properties, and spin-polarized tunneling effect in La 0.5 Ca 0.3 Te 0.2 MnO 3 polycrystalline were studied in details. The temperature dependence of the inverse of the magnetic susceptibility indicates the presence of ferromagnetic exchange interaction between the nearest neighbors at the Weiss temperature θ p  = 265.32 ± 0.109. Based on the magnetic field dependence of magnetization, M(H), and employing the thermodynamic Maxwell equation, the magnetic entropy change |ΔS M | of the studied sample was determined. The maximum entropy change value of the system was around 4.99 J kg −1  K −1 under a magnetic field of 5 T. Electrically, the upturned region of resistivity was observed at low temperature. The recovery of the resistivity was found to be strongly affected by the external magnetic field. The electrical data were analyzed considering various models. Interestingly, the exception of the spin-polarized tunneling (SPT) model is in good agreement with the experimental data among other models. In the current work, the SPT is the dominant mechanism leading to the rise of resistivity, while decreasing the temperature values. Magnetotransport analysis was successfully carried out using percolation model in the temperature range between around 50 K to nearly 300 K under different magnetic fields up to 8 T. The isothermal field dependence of magnetoresistance was recorded fairly well via a phenomenological model based on the spin-polarized tunneling model.
ISSN:1557-1939
1557-1947
DOI:10.1007/s10948-018-4906-2