ENGINEERING MAGNETIC TRANSITIONS AND MAGNETOCALORIC EFFECT IN RARE-EARTH TRANSITION METAL ICOSAGENIDES

George Agbeworvi (8800547)

05 May 2020

<div>The global demand for energy of mankind, the ever-increasing cost of energy, and the expected depletion of fossil energy carriers within the next centuries urge the exploration of alternative and more sustainable ways to provide energy. The current quest for energy-efficient technologies for the replacement of existing cooling devices has made the magnetocaloric effect a field of current scientific interest. Cooling technologies based on magnetic refrigerants are expected to have a better environmental impact compared with those based on the gas compression-expansion cycle. This technology provides an alternative for refrigeration applications with advantages, such as high energy efficiency, environmental friendliness, and low power consumption. In search of promising magnetocaloric materials, several rare earth-depleted transition metal-based materials were designed and investigated.</div><div>In this work, RCrxAl2-x and RZnAl (R = Gd, Tb, Dy, Ho) belonging to the ternary rare-earth transition-metal Laves phases, were chosen as the starting point to establish the effect of valence electron concentration (VEC) on the magnetic behavior and magnetocaloric effect. Our result and the results from the previously studied RTAl phases (T = Cu, Ni, Co, Fe, Mn) shows that the perturbation of the valence electron concentration at the Fermi level is found to be the driving force that dictates the crystal structure, magnetocaloric and magnetic properties of these systems. Most notably, the decrease in the valence electron concentration at the Fermi level leads to an increase in the curie temperature.</div><div>In addition, we have further extended this theory to GdNiAl2 systems. GdNiAl2 is a known magnetocaloric material which exhibits an isothermal magnetic entropy change of ΔSM = 16.0 Jkg-1K-1 at TC = 28K under a magnetic field change from 0-5T. However, the low TC limits its application as a room temperature refrigerant. We, therefore, substituted Co for (Ni/Al) in the structure of GdNiAl2, intending to substantially perturb the position of the Fermi level of Ni since that will lead to a decrease in the VEC and hence elevate the TC. The study was also extended to another Icosagenides (Ga,), which saw the substitution of Ga for Al in GdNiAl2 and its Co substituted analogs. The Ga analogs exhibit complex magnetic behavior with a cascade (multiple) of magnetic transitions, as opposed to the rather simple magnetism of their Al congeners.</div>

Inorganic Chemistry

Solid State Chemistry

Transition Metal Chemistry

Synthesis of Materials

Theory and Design of Materials

magnetocaloric effects

Magnetoresistive Properties

magnetovolume effect

Rare-earth transition metal systems

Intermetallic compouns

Magnetism

Laves phase compounds

Modélisation au sein de la DFT des propriétés des structures électronique et magnétique et de liaison chimique des Hydrures d’Intermétalliques / DFT modeling of the electronic and magnetic structures and chemical bonding properties of intermetallic hydrides

Al Alam, Adel F.

26 June 2009

Cette thèse présente une étude modélisatrice de différentes familles d'intermétalliques et de leurs hydrures qui présentent un intérêt à la fois fondamental et appliqué. Deux méthodes complémentaires construites au sein de la théorie de la fonctionnelle densité (DFT) ont été choisies : d'une part celle à base de pseudo potentiels (VASP) pour l'optimisation géométrique, la recherche structurale et la cartographie de localisation électronique (ELF), d'autre part celle de type "tous-électrons" (ASW), pour une description détaillée de la structure électronique, des propriétés de liaison chimique suivant différents schémas et des quantités impliquant les électrons de c\oe ur comme le champ hyperfin. Un accent particulier est mis sur les rôles compétitifs des effets magnétovolumiques par rapport à ceux chimiques (liaison métal-H) dans les phases hydrurées, binaires de Laves (ex. ScFe2) et de Haucke (ex. LaNi5) et ternaires à base de cérium (ex. CeRhSn) et d'uranium (ex. U2Ni2Sn). / This thesis presents an ab initio study of several classes of intermetallics and their hydrides. These compounds are interesting from both a fundamental and an applied points of view. To achieve this aim two complementary methods, constructed within the DFT, were chosen : (i) pseudo potential based VASP for geometry optimization, structural investigations and electron localization mapping (ELF), and (ii) all-electrons ASW method for a detailed description of the electronic structure, chemical bonding properties following different schemes as well as quantities depending on core electrons such as the hyperfine field. A special interest is given with respect to the interplay between magnetovolume and chemical interactions (metal-H) effects within the following hydrided systems : binary Laves (e.g. ScFe2) and Haucke (e.g. LaNi5) phases on one hand, and ternary cerium based (e.g. CeRhSn) and uranium based (e.g. U2Ni2Sn) alloys on the other hand.

Hydrures d'intermétalliques

Dft

Méthode pseudopotentiel

Méthode tous-électrons

Phases de Laves

Phases de Haucke

Effet magnétovolumique

Liaison chimique

Magnétisme itinérant et localisé

Magnétisme covalent

Théorie de Stoner du champ moyen

Terme de contact de Fermi