AI Article Synopsis
- This study focuses on cubic double halide perovskites RbOsX (where X = Cl, Br, and I), examining their structural, electronic, and mechanical properties through density functional calculations.
- The results indicate that these compounds are stable in a ferromagnetic phase, showing good agreement with existing theoretical data regarding lattice parameters and mechanical stability, confirmed by positive cohesive energy and phonon spectrum analysis.
- These materials exhibit half-metallic behavior and strong ferromagnetic alignment, suggesting promising applications in spintronics, with mechanical properties showing they are both isotropic and ductile.
Article Abstract
In this work, we present a density functional calculation of the structural, electronic, and mechanical properties of cubic double halide perovskites RbOsX (X = Cl, Br, and I). Our results show that these compounds are stable in the ferromagnetic phase with lattice parameters, bulk modulus, and their first-pressure derivatives in good agreement with other available theoretical data. The negative values of cohesive energy and formation energy, along with the absence of negative or imaginary frequencies in the phonon spectrum, confirm the mechanical stability of all the compounds. The Curie temperature (Tc) is determined using a Heisenberg model in the mean-field approximation. We obtained a half-metallic character for all compounds, making them promising materials for spintronic applications. The magnetic properties indicate that the Os atoms in all compounds are responsible for the magnetism, while the positive exchange constants suggest a strong preference for ferromagnetic alignment. This indicates a stable ferromagnetic phase and potential applications in spintronics. The mechanical properties demonstrate that the compounds studied are isotropic and ductile.
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| http://dx.doi.org/10.1002/jcc.27537 | DOI Listing |
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