Des interfaces reelles metal/MgO(001) au transport dans les jonctions tunnel epitaxiees

Sicot, Muriel

30 September 2005

Cette thèse présente une étude des interfaces métal de transition ferromagnétique/oxyde et leur importance dans les mécanismes de transport tunnel polarisé en spin. Le travail a porté sur des bicouches ultraminces NiMnSb/MgO(001), Fe/ MgO(001), Co/ MgO(001) et Mn/ MgO(001) élaborées par épitaxie par jets moléculaires. L'originalité de ce travail réside dans l'étude approfondie des propriétés électroniques du matériau magnétique en contact avec la barrière d'oxyde : hybridation, polarisation et magnétisme à l'interface ont été étudiés en utilisant les techniques de laboratoire ainsi que le rayonnement synchrotron. Parallèlement, l'étude des effets magnétorésistifs dans des jonctions tunnel totalement épitaxiées Fe/MgO/Fe(001) a apporté des preuves du filtrage par la barrière MgO des ondes de Bloch en fonction de leur symétrie. Enfin, nous avons mis en évidence l'influence de la qualité structurale et chimique de l'interface Fe/MgO et des électrodes sur ces mécanismes.

[PHYS:PHYS] Physics/Physics

MgO

jonction tunnel magnétique

NiMnSb

rayonnement synchrotron

<br />filtrage en spin

transport tunnel

demi-metaux

demi-metal

Fe

Co

Mn

demi heussler

polarisation

tunnel

interfaces

dichroisme magnetic circulaire

XMCD

XPS

photoemission

Theoretical Investigations Of Core-Level Spectroscopies In Strongly Correlated Systems

Gupta, Subhra Sen

12 1900

Ever since the discovery of exotic phenomena like high temperature (Tc) superconductivity in the cuprates and colossal magnetoresistance in the manganites, strongly correlated electron systems have become the center of attention in the field of condensed matter physics research. This renewed interest has been further kindled by the rapid development of sophisticated experimental techniques and tremendous computational power. Computation plays a pivotal role in the theoretical investigation of these systems, because one cannot explain their complicated phase diagrams by simple, exactly solvable models. Among the plethora of experimental techniques, various kinds of high energy electron spectroscopies are fast gaining importance due to the multitude of physical properties and phenomena which they can access. However the physical processes involved and the interpretation of the spectra obtained from these spectroscopies are extremely complex and require extensive theoretical modelling. This thesis is concerned with the theoretical modelling of a certain class of high energy electron spectroscopies, viz. the core-level electron spectroscopies, for strongly correlated systems of various kinds. The spectroscopies covered are Auger electron spectroscopy (AES), core-level photoemission spectroscopy (core-level PES) and X-ray absorption spec- troscopy (XAS), which provide non-magnetic information, and also X-ray magnetic circular and linear dichroism (XMCD and XMLD), which provide magnetic information. .

Spectroscopy

High Temperature Superconductors

Electronic Structure

High Energy Electron Spectroscopies

Auger Electron Spectroscopy (AES)

X-ray Absorption Spectroscopy (XAS)

X-ray Magnetic Circular Dichroism (XMCD)

X-ray Magnetic Linear Dichroism (XMLD)

Strong Correlations

Manganites

Unusal Doping

Magneto-crystalline Anisotropy

Optics

L'anisotropie magnétique perpendiculaire induite par oxydation et recuit thermique : de la structure au magnétisme / The magnetic anisotropy induced by oxidation and thermal annealing : From structure to magnetism

Mohamed Garad, Houmed

03 April 2012

Dans le domaine des couches minces (épaisseur~Å) associant un métal magnétique (Fe, Co, Ni) et un élément non magnétique (essentiellement métallique ou isolant), de remarquables propriétés physiques (aimantation, transport) nécessitent des caractérisations structurales fines. En particulier, citons le cas de jonctions tunnel (métal/isolant/métal) à aimantation perpendiculaire qui sont en cours d'étude au laboratoire Spintec (UMR8191 (CEA/CNRS/UJF). Ces nanomatériaux sont déposés par voie physique (pulvérisation cathodique) au sein de ce laboratoire. Ces nanostructures sont également sondées par diffraction aux rayons X au sein de l'Institut Néel (UPR 2940) via une collaboration entre Spintec et une équipe de cet Institut (Surface, interfaces et nanostructures du Département MCMF, Matière Condensée, Matériaux, et Fonctions). Ces mesures de réflectivité X constituent la sonde privilégiée de choix dans la cadre de cette thèse. D'autres voies sont également exploitées: à l'aide des moyens de rayonnement synchrotron tels que la spectroscopie d'absorption de rayons X : EXAFS, XANES et XMCD. La thèse aura pour but d'étudier expérimentalement ces phénomènes en couches continues sur ces empilements à jonction tunnel avec aimantation perpendiculaire. Plus précisément, le travail de thèse permettra de comprendre les mesures magnétiques (effectuées à l'institut Néel notamment par magnétométrie SQUID et HALL à basse température) grâce à une batterie de mesures structurales (diffraction aux rayons X, rasant, figures de pôles, réflectivité, absorption X …). Notamment, l'influence des paramètres de dépôt (types de couches, épaisseurs, recuits) du matériau sont étudiées via la collaboration entre les différents groupes de recherche précédemment cités. Cette thématique s'inscrit d'une part dans le cadre de travaux menés à Spintec et dédiés à la recherche de nouveaux matériaux à forte valeur ajoutée industrielle (sur le stockage d'information à ultrahaute densité sur media discrets par exemple). Elle s'inscrit d'autre part dans le renforcement de liens entre recherches fondamentales (laboratoire propre du CNRS comme l'institut Néel) et appliquées (CEA), avec un recours aux solides compétences en caractérisations structurales et magnétiques de l'Institut Néel. / In the domain of thin film (thickness ~ Å) combining a magnetic metal (Fe, Co, Ni) and a non-magnetic (largely metal or insulator), remarkable physical properties (magnetization, transport) require fine structural characterization. In particular, include the case of tunnel junctions (metal / insulator / metal) with perpendicular magnetization which are being studied in the laboratory Spintec (UMR8191 (CEA / CNRS / UJF). These nanomaterials are deposited by physical (sputtering) in this laboratory. These nanostructures are probed by X-ray diffraction in the Neel Institute (UPR 2940) via collaboration between Spintec and a team of the Institute (Surface, Interfaces and Nanostructures Department MCFP, Condensed Matter Materials and Functions). These reflectivity measurements X are the preferred sensor of choice in the context of this thesis. Other routes are also used: using means such as synchrotron radiation absorption spectroscopy X-ray: EXAFS, XANES and XMCD. The thesis will aim to study these phenomena experimentally in continuous layers on the tunnel junction stacks with perpendicular magnetization. Specifically, the thesis will include the magnetic measurements (performed at the Institut Néel SQUID magnetometry including HALL and low temperature) through a battery of structural. This theme is part of a share in the context of work carried Spintec and dedicated to research of new materials with high added value industries (information storage on ultra-high density of discrete media for example). It registers on the other hand in strengthening links between basic research (CNRS own laboratories as Neel Institute) and applied (ECA), with strong skills in use of structural and magnetic characterization of the Institute Neel.

Couches minces

Anisotropie perpendiculaire

Reflectivité aux Rays X

Structures Metal/isolant

Extraordinary Hall Effect

X Rays Absorption( EXAFS , XANES )

Magnetic layered films

Perpendicular Magnetic Anisotropy

X rays Reflectivity

Metal/Insulator structures

Extraordinary Hall Effect

530

X-ray spectroscopic and magnetic investigations of selected manganese-containing molecularhigh-spin complexes

Prinz, Manuel

08 July 2009

The presented thesis includes investigations to fully characterize the electronic structure and magnetic properties ofselected manganese containing high-spin molecules by means of various X-ray spectroscopic, magnetic and theoretical methods. The investigations on the Mn4 star-shaped molecule havelead to a number of interesting results. Magneto-chemical studies exhibit very weak exchange coupling constantsbetween the four Mn(II) ions, leading to complicated low lying states in which the ground state is not well separated, resulting from a dominant weak ferromagnetic coupling and a giant moment of up to 20 µB/f.u. XMCD measurements revealed that almost the completemagnetic moment is located around the Mn(II) ions.This is in agreement with only a few charge transfer states foundwithin the detailed X-ray absorption spectroscopic study. The electronic structure and detailed magnetic properties of the star-shaped heteronuclear CrIIIMnII3 complex have been precisely investigated.With XPS the homovalency of Mn and Cr have been verified. The XA-spectra of the manganese and chromium L edges were measured and compared to earlier investigated Mn4 spectra.The combination high-magnetic field magnetic measurements and element selective XMCD of Mn and Cr L edges and quantum model calculations lead to a complete analysis of the magnetic structure of the CrMn3 magnetic core. The III valence state of the manganese ions in MnIII6O2Salox has been verified. From X-ray diffraction, typical Jahn-Teller distorted oxygen octahedra have been found for Mn(III) ions. Comparisons of XPS and XAS spectra of the complex to corresponding spectraof maganite and tetranuclear manganese(II) cluster it was definitely possible to identify MnIII6O2Salox as a pure Mn(III) compound.

molecular magnetism

high-spin molecules

maganese

XPS

XAS

XMCD

29 - Physik, Astronomie

75.50.Xx - Molecular magnets

78.70.Dm - X-ray absorption spectra

87.64.Kn

ddc:540

Structural and magnetic properties of ultrathin Fe3O4 films: cation- and lattice-site-selective studies by synchrotron radiation-based techniques

Pohlmann, Tobias

19 August 2021

This work investigates the growth dynamic of the reactive molecular beam epitaxy of Fe3O4 films, and its impact on the cation distribution as well as on the magnetic and structural properties at the surface and the interfaces. In order to study the structure and composition of Fe3O4 films during growth, time-resolved high-energy x-ray diffraction (tr-HEXRD) and time-resolved hard x-ray photoelectron spectroscopy (tr-HAXPES) measurements are used to monitor the deposition process of Fe3O4 ultrathin films on SrTiO3(001), MgO(001) and NiO/MgO(001). For Fe3O4\SrTiO3(001) is found that the film first grows in a disordered island structure, between thicknesses of 1.5nm to 3nm in FeO islands and finally in the inverse spinel structure of Fe3O4, displaying (111) nanofacets on the surface. The films on MgO(001) and NiO/MgO(001) show a similar result, with the exception that the films are not disordered in the early growth stage, but form islands which immediately exhibit a crystalline FeO phase up to a thickness of 1nm. After that, the films grown in the inverse spinel structure on both MgO(001) and NiO/MgO(001). Additionally, the tr-HAXPES measurements of Fe3O4/SrTiO3(001) demonstrate that the FeO phase is only stable during the deposition process, but turns into a Fe3O4 phase when the deposition is interrupted. This suggests that this FeO layer is a strictly dynamic property of the growth process, and might not be retained in the as-grown films. In order to characterize the as-grown films, a technique is introduced to extract the cation depth distribution of Fe3O4 films from magnetooptical depth profiles obtained by fitting x-ray resonant magnetic reflectivity (XRMR) curves. To this end, x-ray absorption (XAS) and x-ray magnetic circular dichroism (XMCD) spectra are recorded as well as XRMR curves to obtain magnetooptical depth profiles. To attribute these magnetooptical depth profiles to the depth distribution of the cations, multiplet calculations are fitted to the XMCD data. From these calculations, the cation contributions at the three resonant energies of the XMCD spectrum can be evaluated. Recording XRMR curves at those energies allows to resolve the magnetooptical depth profiles of the three iron cation species in Fe3O4. This technique is used to resolve the cation stoichiometry at the surface of Fe3O4/MgO(001) films and at the interfaces of Fe3O4/MgO(001) and Fe3O4/NiO. The first unit cell of the Fe3O4(001) surface shows an excess of Fe3+ cations, likely related to a subsurface cation-vacancy reconstruction of the Fe3O4(001) surface, but the magnetic order of the different cation species appears to be not disturbed in this reconstructed layer. Beyond this layer, the magnetic order of all three iron cation species in Fe3O4/MgO(001) is stable for the entire film with no interlayer or magnetic dead layer at the interface. For Fe3O4/NiO films, we unexpectedly observe a magnetooptical absorption at the Ni L3 edge in the NiO film corresponding to a ferromagnetic order throughout the entire NiO film, which is antiferromagnetic in the bulk. Additionally, the magnetooptical profiles indicate a single intermixed layer containing both Fe2+ and Ni2+ cations.

magnetic thin films

magnetite

Fe3O4

synchrotron radiation

XRD

XAS

XMCD

XRMR

XRR

33.75 - Magnetische Materialien

68.47.Gh - Oxide surfaces

75.70.Rf - Surface magnetism

ddc:530

Investigation of the magnetic and electronic structure of Fe in molecules and chalcogenide systems

Taubitz, Christian

09 June 2010

In this work the electronic and magnetic structure of the crystals Sr2FeMoO6, Fe0.5Cu0.5Cr2S4, LuFe2O4 and the molecules FeStar, Mo72Fe30, W72Fe30 are investigated by means of X-ray spectroscopic techniques. These advanced materials exhibit very interesting properties like magnetoresistance or multiferroic behaviour. In case of the molecules they also could be used as spin model systems. A long standing issue concerning the investigation of these materials are contradicting results found for the magnetic and electronic state of the iron (Fe) ions present in these compounds. Therefore this work focuses on the Fe state of these materials in order to elucidate reasons for these problems. Thereby the experimental results are compared to multiplet simulations.

Fe valence state

Advanced materials

XPS, XAS, XMCD

Magnetoresistance

33.61 - Festkörperphysik

33.30 - Atomphysik, Molekülphysik

71.70.Ch - Crystal and ligand fields

75.47.Gk - Colossal magnetoresistance

ddc:530