Structural, Thermodynamic and Magneto-Electronic Properties of Cd0.75Cr0.25Se and Zn0.75Cr0.25S: An Ab-Initio Study
S. Amaria, b, S. Daoudc, H. Rekab-Djabrid, e
aLaboratoire de Modélisation et Simulation en Sciences des Matériaux, Université Djillali Liabès de Sidi Bel-Abbès, Sidi Bel-Abbès, 22000, Algeria
bFaculty of Nature and Life Science, Hassiba Benbouali University of Chlef, 02000, Algeria
cLaboratory of Materials and Electronic Systems, Mohamed El Bachir El Ibrahimi University of Bordj Bou Arreridj, 34000, Bordj Bou Arreridj, Algeria
dLaboratory of Micro and Nanophysics (LaMiN), National Polytechnic School Oran, ENPO-MA, BP 1523, El M'Naouer, 31000, Oran, Algeria
eFaculty of Nature and Life Sciences and Earth Sciences, Akli Mohand-Oulhadj University, 10000, Bouira, Algeria
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Using the full-potential linearized augmented plane wave plus local orbital method based on spin-polarized density functional theory, we investigate the parameters of the structure, the electronic, magnetic, and thermodynamic properties of cubic zinc-blende Cd0.75Cr0.25Se and Zn0.75Cr0.25S ordered ferromagnetic materials. We adopt the Perdew-Burke-Ernzerhof generalized gradient approximation and the modified Becke-Johnson exchange potential for the exchange-correlation energy and potential. Furthermore, the effect of high pressure on the normalized unit cell volume, bulk modulus, and Grüneisen parameter for both CdSe and ZnS binary compounds as well as for Cd0.75Cr0.25Se and Zn0.75Cr0.25S partially substituted materials was also predicted. The results indicate that both these materials are stabilized in the ferromagnetic phase. Using the modified Becke-Johnson approach and Perdew-Burke-Ernzerhof generalized gradient approximation, our calculations also demonstrate that both Cd0.75Cr0.25Se and Zn0.75Cr0.25S alloys are semiconductors with the magnetic moment of 4 μB per formula unit. Furthermore, the calculations of the s-d exchange constant and p-d exchange constant clearly indicate the magnetic nature of these compounds. Finally, in order to gain further information, basic thermodynamic properties such as heat capacity, thermal expansion coefficient, and entropy have been explored using the quasi-harmonic Debye model.

DOI:10.12693/APhysPolA.143.36
topics: density functional theory (DFT), magnetic semiconductors, thermodynamic properties, electronic structure