The half metallic feature at high temperature of the novel half-Heusler alloys and their [100] oriented layered superlattices: A DFT investigations

• Published in: Materials chemistry and physics Vol. 267; p. 124712
• Main Authors: Elahmar, Mohamed Hichem, Rached, Habib, Rached, Djamel
• Format: Journal Article
• Language: English
• Published: Lausanne Elsevier B.V 15.07.2021; Elsevier BV
• Subjects: Ambient temperature; Curie temperature; DFT calculations; Electronic properties; Ferromagnetic materials; Figure of merit; Free energy; Heat of formation; Heusler alloys; High spin polarization; High temperature; HM ferromagnetism; Investigations; Magnetic properties; Mathematical analysis; Polarization (spin alignment); Seebeck effect; Superlattices; Superlattices materials; Thermal conductivity; Thermoelectric materials; Tin compounds; HM ferromagnetism; High spin polarization; Superlattices materials; DFT calculations
• ISSN: 0254-0584; 1879-3312
• DOI: 10.1016/j.matchemphys.2021.124712

Herein, we have investigated by means of the DFT calculations the magneto-electronic properties and thermoelectric responses of the novel half-Heusler NbFe(Mn)Sn compounds and their layered superlattices growing along [100] direction. The ground-state properties and magnetic stability revealed that the bulk compounds were ferromagnetic materials. The formation energy was determined meticulously and revealed that the studied materials could be synthesized experimentally. The half-metallic ferromagnetism with the presence of the strong p-d hybridization have been strongly confirmed from the magneto-electronic calculations for all the studied materials. The Curie temperature was estimated from the mean field approach, the obtained values exceed the ambient temperature. Furthermore, the thermoelectric response was evaluated and categorized the investigated compounds as a good thermoelectric materials due to the high figure of merit, large Seebeck coefficient and low electronic part of thermal conductivity. The curve of spin polarization (SP) as a function of temperature divulged that the 100% SP was conserved at high temperature for NbFeSn and superlattice materials. The phonon dispersion was calculated in order to examine the dynamic stabilities of the studied materials. The present detailed study made these materials as a potential candidates for spintronic thermoelectric devices. [Display omitted] •The of NbFe(Mn)Sn compounds and their layered superlattices were investigated.•The bulk and superlattice materials exhibit half-metallic ferromagnetism with strong p-d hybridization.•The thermoelectric response disclose the maintaining of half-metallic ferromagnetism at high temperature.•A good electrical response at high temperature was found for these materials.•The studied compounds have proved to be an efficient candidates for thermoelectric spintronic devices.