Three-Dimensional Finite Element Modeling of Multilayered Multiferroic Composites

Wang, Ruifeng

08 August 2011

No description available.

Civil Engineering

Engineering

Materials Science

Mechanical Engineering

Finite Element

Multiferroic

Magnetoelectric Effect

Piezoelectric

Multilayered Composite

Functionally Graded Material

ABAQUS UEL

Barium Titanate-Based Magnetoelectric Nanocomposites

Yang, Yaodong

28 July 2011

Barium Titanate (BaTiO3 or BTO) has attracted an ever increasing research interest because of its wide range of potential applications. Nano-sized or nanostructured BTO has found applications in new, useful smart devices, such as sensors and piezoelectric devices. Not only limited to one material, multi-layers or multi-phases can lead to multifunctional applications; for example, nanocomposites can be fabricated with ferrite or metal phase with BTO. In this study, I synthesized various BTO-ferrites, ranging from nanoparticles, nanowires to thin films. BTO-ferrite coaxial nanotubes, BTO-ferrite self-assemble thin films, and BTO single phase films were prepared by pulsed laser deposition (PLD) and sol-gel process. BTO-ferrite nanocomposites were grown by solid state reaction. Furthermore, BTO-metal nanostructures were also synthesized by solid state reaction under hydrogen gas which gave us a great inspiration to fabricate metal-ceramic composites. To understand the relationship between metal and BTO ceramic phase, I also deposited BTO film on Au buffered substrates. A metal layer can affect the grain size and orientation in BTO film which can further help us to control the distribution of dielectric properties of BTO films. After obtaining different nanomaterials, I am interested in the applications of these materials. Recently, many interesting electric devices are developed based on nanotechnology, e.g.: memristor. Memristor is a resistor with memory, which is very important in the computer memory. I believe these newly-synthesized BTO based nanostructures are useful for development of memristor, sensors and other devices to fit increasing needs. / Ph. D.

metal-ceramic

Barium Titanate

ferroelectric

piezoelectric

multiferroic

self-assemble

magnetoelectric

nanocomposite

nanorod

thin film

pulsed laser deposition

Multiferroic hexagonal HoMnO3 films

Kim, Jong-Woo

18 January 2010

The fundamental properties of hexagonal multiferric HoMnO3 films have been thoroughly investigated. The films are grown by pulsed laser deposition on Y:ZrO2(111) substrates. High quality epitaxial HoMnO3 films of 25 { 1000 nm thickness were successfully prepared. The film properties are compared to those of single-crystals. The magnetization measurements revealed that the films show a deviating magnetic behavior from the single-crystals in several ways. For instance, the films have a weakened antiferromagnetic Ho3+ order confirmed from magnetic susceptibility. The difierences are likely to be related to the modified (mostly larger) lattice parameters of films. An approximate phase diagram in comparison with the single-crystal's one is constructed. For multiferroicity investigations, Second Harmonic Generation (SHG; in collaboration with the group of M. Fiebig) has been employed. By SHG, the ferroelectric polar order of the films is obviously confirmed. The ferroelectric switching at room temperature could be clearly demonstrated, whereas leakage of films requires generally a more sophisticated approach. / Die fundamentalen Eigenschaften von hexagonalen multiferroischen HoMnO3 Schichten werden eingehend untersucht. Die dünnen Schichten wurden mittels gepulster Laserdeposition auf Y:ZrO2(111)-Substraten gewachsen. Hochwertige epitaktische HoMnO3-Dünnschichten von 25 { 1000 nm Dicke wurden erfolgreich hergestellt. Die Dünnschichteigenschaften werden mit denen von Einkristallen verglichen. Die Magnitisierungsmessungen ergeben, dass die dünnen Schichten ein von den Einkristallen in verschiedener Weise abweichendes magnetischen Verhalten zeigen. Zum Beispiel haben die dünnen Schichten eine abgeschwächte antiferromagntetische Ho3+ Ordnung, die durch die magnetische Suszeptibilität bestätigt wird. Die Unterschiede sind wahrscheinlich auf die veränderten (meistens grösseren) Gitterparameter der dünnen Schichten zurückzuführen. Ein Phasendiagramm wird zum Vergleich mit Einkristallen konstruiert. Durch Second Harmonic Generation (SHG; in Zusammenarbeit mit der Gruppe von M. Fiebig) wird die ferroelektrische Ordnung der dünnen Schichten eindeutig bestätigt. Das ferroelektrische Umschalten bei Raumtemperatur kann eindeutig nachgewiesen werden, wobei durch den Leckstrom der dünnen Schichten allgemein eine detailliertere Vorgehensweise benötigt wird.

multiferroic

magnetoelectric

hexagonal HoMnO3 thin film

rare-earth manganite

pulsed laser deposition (PLD)

multiferroisch

magnetoelektrisch

hexagonal HoMnO3 Schichten

Seltenerden Manganat

gepulster Laserdeposition

ddc:620

rvk:UP 7500

Theoretical determination of electric field-magnetic field phase diagrams of the multiferroic bismuth ferrite

Allen, Marc Alexander

28 August 2014

Bismuth ferrite (BFO) is a multiferroic material with cross-correlation between magnetic and electric orders. With no applied external fields the spin structure of BFO is anitferromagnetic and cycloidal. This ordering prevents the detection of the weak ferromagnetism known to exist in the material. The application of magnetic and electric fields of suitable strength and direction is capable of compelling the Fe3+ spins to align in a homogeneous, antiferromagnetic fashion. This report details how numerical methods were used to simulate the spin alignment of a BFO system under different fields. The results were compiled into electric field-magnetic field phase diagrams of BFO to show the divide between cycloidal and homogeneous systems. / Graduate / 0607 / 0611 / marca@uvic.ca

bismuth ferrite

multiferroic

magnetism

ferroelectricity

antiferromagentism

numerical methods

condensed matter

magnetoelectric effect

Dzyaloshinskii-Moriya interaction

spin-current effect

weak ferromagnetism

electric field

magnetic field

BFO

BiFeO3

Relação entre os métodos de síntese de precursores particulados ferroicos e a obtenção de compósitos magnetoelétricos texturados

Paranhos, Rafael Rodrigo Garofalo

04 September 2015

Submitted by Daniele Amaral (daniee_ni@hotmail.com) on 2016-10-07T19:22:08Z No. of bitstreams: 1 TeseRRGP.pdf: 3041523 bytes, checksum: f8585bab1f9c1565717516794f4e8831 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-10-20T19:31:28Z (GMT) No. of bitstreams: 1 TeseRRGP.pdf: 3041523 bytes, checksum: f8585bab1f9c1565717516794f4e8831 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-10-20T19:31:35Z (GMT) No. of bitstreams: 1 TeseRRGP.pdf: 3041523 bytes, checksum: f8585bab1f9c1565717516794f4e8831 (MD5) / Made available in DSpace on 2016-10-20T19:31:43Z (GMT). No. of bitstreams: 1 TeseRRGP.pdf: 3041523 bytes, checksum: f8585bab1f9c1565717516794f4e8831 (MD5) Previous issue date: 2015-09-04 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / This study analyses the relationships between synthesis routes and physical properties of the composite system 67.5(PbMg1/3Nb2/3O3) +32.5(PbTiO3), or simply PMN-PT, as ferroelectric phase and BaFe12O19, or BaM, as magnetic phase. The choice of phases was based on the exceptional properties that both PMN-PT and BaM possess: solid solutions of the complex perovskite PMN-PT in both monocrystalline and polycrystalline forms, particularly those whose composition lies within the region of morphotropic boundary phases, have the largest known piezoelectric coefficients. BaM, or barium hexaferrite, presents relatively high property anisotropy due to its hexagonal crystal structure (expressed in particles that grow in nonequiaxed format) and easy magnetization along the c-Crystallographic axis. Thus, the main objective of this work was to obtain and characterize magnetoelectric composites (either volumetric or as two-dimensional nanostructures) textured from PMN-PT/BaM, by exploiting the quasi-piezomagnectic characteristics and the microstructural, crystallographic and magnetic anisotropyof the BaM phase. With a molar ratio of 80/20 between the ferroelectric and magnetic phases, different routes of synthesis and processing were used for the production of threedimensional ceramic composites with 0-3 connectivity, or thin films with 0-3 and 2-2 connectivity.The Pechini, sol-gel, co-precipitation,and solid state reaction techniques were applied for the synthesis of powders and/or solutions; the pressure-assisted sintering method was used for the densification of three-dimensional bodies; and the spin-coating technique was employed for the deposition of films. Physical, electrical, magnetic and magnetoelectric characterizations were performed in order to clarify the influence of the BaM phase upon composites of different configurations. In a prospective yet not exhaustive manner, relations were assessed among the experimental parameters of the various synthesis routes (with greater focus on the barium hexaferrite phase) and the production of ceramic composites of PMNPT/ BaM system. It was found that the final characteristics of the prepared materials, particularly the hysteresis behavior of the magnetoelectric coefficient as a function of applied magnetic field, were highly susceptible to variations in the morphology, size and orientation of barium hexaferrite grains, which, in turn, depended on the synthesis and sintering routes applied. / Realizaram-se estudos de síntese e de caracterização das propriedades físicas do sistema compósito 67,5(PbMg1/3Nb2/3O3) +32,5(PbTiO3), ou simplesmente PMN-PT, como fase ferroelétrica, e da BaFe12O19, ou BaM, como fase magnética. A escolha dessas fases baseou-se nas propriedades excepcionais que ambas apresentam. A perovskita complexa PMN-PT, tanto na forma monocristalina como policristalina, apresenta soluções sólidas com os maiores coeficientes piezoelétricos conhecidos, particularmente as de composição na região do contorno morfotrópico de fases, como é o caso da 32,5%mol de PT. A fase BaM, ou hexaferrita de bário, apresenta relativamente alta anisotropia de propriedades magnéticas devido à sua estrutura cristalográfica hexagonal (refletida em partículas que crescem em formato não equiaxial) e fácil magnetização ao longo do eixo cristalográfico-c. O objetivo principal deste trabalho foi a obtenção e a caracterização de compósitos magnetoelétricos (volumétricos ou como nanoestruturas bidimensionais) texturados de PMN-PT/BaM, explorando-se as características quasi-piezomagnéticas e a anisotropia microestrutural/cristalográfica/magnética da fase BaM. Com uma proporção molar de 80/20 entre a fase ferroelétrica e a magnética, foram utilizadas diferentes rotas de síntese e de processamento de materiais para a produção de compósitos com conectividade 0-3, quando no caso de corpos cerâmicos volumétricos; ou 0-3 e 2-2, quando no caso de filmes finos. Os métodos Pechini, sol-gel, de copreciptação e de reação no estado sólido foram utilizadas na síntese dos pós e/ou soluções; o método de sinterização assistida por pressão, para a densificação dos corpos volumétricos, e a técnica “spin-coating”, para a deposição dos filmes. As caracterizações físicas, elétricas, magnéticas e magnetoelétricas buscaram evidenciar a influência das propriedades da fase BaM nas diferentes configurações de compósitos. De forma prospectiva e ainda não exaustiva, foram avaliadas as relações entre os parâmetros experimentais das diversas rotas de síntese (com maior foco na fase hexaferrita de bário) e a produção de compósitos cerâmicos do sistema PMN-PT/BaM. Encontrou-se que as características finais dos materiais preparados, em especial o comportamento histerético do coeficiente magnetoelétrico em função do campo magnético aplicado, foram altamente susceptíveis às variações da morfologia, tamanho e orientação dos grãos da hexaferrita de bário, que, por sua vez, dependem das rotas de síntese e de sinterização aplicadas.

Compósito magnetoelétrico

Acoplamento ME self-bias

Texturização

Orientação preferencial

Propriedades magnéticas

Magnetoelectric composite

Self-bias coupling

Texture

Preferred orientation

Magnetic properties

Ferroelectric properties

CIENCIAS EXATAS E DA TERRA

Ordres électriques et magnétiques dans le composé magnétoélectrique GaFeO3 : optimisation par dopage / Electrical and magnetic orders in the magnetoelectric compound GaFeO3 : optimization through cationic doping

Thomasson, Alexandre

17 September 2013

Les concepts de matériaux multiferroïques et/ou magnétoélectriques permettent d’envisager de nouveaux dispositifs de mémoires plus performants et moins consommateurs d’énergie. Malheureusement de tels matériaux présentant ces propriétés à température ambiante ne sont pour l’instant pas disponibles. Les matériaux qui font l’objet des études présentées dans ce manuscrit, les ferrites de gallium Ga2-xFexO3, 0,7 ≤ x ≤ 1,4, sont d’excellents candidats. Le présent travail de thèse en a étudié les propriétés électriques, tant sur matériaux massifs que couches minces. Nous avons mesuré une polarisation sur composés massifs du même ordre de grandeur que celle précédemment déterminée par calculs ab initio. Une considérable réduction des courants de fuite habituellement observés en couches minces a été possible grâce à la substitution de Fe2+ par Mg2+. Une polarisation réversible et un effet magnétoélectrique ont alors pu être mis en évidence. Compte tenu du caractère ferrimagnétique à température ambiante des couches minces considérées, ceci constitue la première manifestation d’un matériau multiferroïque et magnétoélectrique à réel intérêt applicatif. / Concepts of multiferroic and magnetoelectric materials allow designing new memory devices with better performances and less energy consumption. Unfortunately, such materials with room temperature applicability are not yet available.The material concerned by this study, gallium ferrites Ga2-xFexO3, 0.7 ≤ x ≤ 1.4, are excellent candidates for such applications. This work aimed at studying the electrical properties of the bulk material, as well as in thin films. We have measured a polarization on the bulk samples comparable to the value estimated by first principle calculations. A considerable reduction of the leakage currents usually observed in oxide thin films has been achieved by the doping by substitution of Fe2+ in the structure, using Mg2+. A switchable polarization and a magnetoelectric effect at room temperature in thin films have been observed. Considering the room temperature ferrimagnetic behavior of this compound, this is the first manifestation of a multiferroic and magnetoelectric with real potential and technological applications.

Oxydes fonctionnels en couche mince

Magnétoélectrique

Multiferroïque

Courants de fuite

Ablation laser

Dopage cationique

Functional thin film oxides

Magnetoelectric

Multiferroic

Leakage current

Pulsed laser deposition

Cationic substitution

537

621.3

Theoretical study of electronic structure and magnetism in materials for spintronics / Etude théorique de la structure électronique et magnétique des matériaux pour la spintronique

Ibrahim, Fatima

31 January 2014

L'avenir de la spintronique repose sur le développement de matériaux ayant des propriétés magnétiques remarquables. L'objectif de cette thèse est de comprendre la physique des deux matériaux fonctionnels proposés pour des applications spintroniques qui utilisent des simulations de la densité fonctionnelle.Nous nous sommes intéressés dans une première partie au ferrite de gallium pour lequel il a été montré que les propriétés dépendaient de la concentration de fer.Les spectres optiques ont été calculés et comparés aux spectres expérimentaux suggérant des niveaux élevés de désordre. Dans la deuxième partie, nous avons montré une polarisation de spin à l’interface hybride formée entre la phthalocyanine de manganèse et la surface de cobalt,en accord avec les expériences de photoémission.La formation de la spinterface a été expliquée par différents mécanismes d'hybridation dans chaque canal de spin.Cette polarisation de spin est coordonnée avec des moments magnétiques induits sur les sites moléculaires. / The future of the spintronics technology requires developing functional materials with remarkable magnetic properties. The aim of this thesis is to understand the physics of functional materials proposed for spintronic applications using ab-initio density functional simulations. We investigated the properties of two different functional materials. We first studied the magnetoelectric gallium ferrite GFO. The dependence of the different properties on the iron concentration has been demonstrated and discussed. The optical spectra were calculated and compared to the experimental once suggesting high levels of iron disorder. In the second part, we demonstrated a highly spin polarized hybrid interface formed between manganese phthalocyanine and cobalt surface in agreement with photoemission experiments. The formation of this spinterface was described by different hybridization mechanisms in each spin channel. This high spin polarization is coordinated with induced magnetic moments on the molecular sites.

Ab-initio

Spintronique moléculaire

Magnetoeléctrique multiferroic

Ferrite de gallium

Phthalocyanine

Spinterface

Ab-initio calculations

Molecular spintronics

Magnetoelectric multiferroics

Gallium ferrite

Phthalocyanine

Spinterface

530.41

Targeted and Controlled Anticancer Drug Delivery and Release with Magnetoelectric Nanoparticles

Rodzinski, Alexandra

04 November 2016

A major challenge of cancer treatment is successful discrimination of cancer cells from healthy cells. Nanotechnology offers multiple venues for efficient cancer targeting. Magnetoelectric nanoparticles (MENs) are a novel, multifaceted, physics-based cancer treatment platform that enables high specificity cancer targeting and externally controlled loaded drug release. The unique magnetoelectric coupling of MENs allows them to convert externally applied magnetic fields into intrinsic electric signals, which allows MENs to both be drawn magnetically towards the cancer site and to electrically interface with cancer cells. Once internalized, the MEN payload release can be externally triggered with a magnetic field. MENs uniquely allow for discrete manipulation of the drug delivery and drug release mechanisms to allow an unprecedented level of control in cancer targeting. In this study, we demonstrate the physics behind the MEN drug delivery platform, test the MEN drug delivery platform for the first time in a humanized mouse model of cancer, and characterize the biodistribution and clearance of MENs. We found that MENs were able to fully cure the model cancer, which in this case was human ovarian carcinoma treated with paclitaxel. When compared to conventional magnetic nanoparticles and FDA approved organic PLGA nanoparticles, MENs are the highest performing treatment, even in the absence of peripheral active targeting molecules. We also mapped the movement through peripheral organs and established clearance trends of the MENs. The MENs cancer treatment platform has immense potential for future medicine, as it is generalizable, personalizable, and readily traceable in the context of treating essentially any type of cancer.

magnetoelectric nanoparticles

magnetic nanoparticles

personalized medicine

cancer

nanomedicine

nanotechnology

drug delivery

nanoparticle biodistribution

Cancer Biology

Medical Biophysics

Medical Biotechnology

Nanomedicine

Nanotechnology

Oncology

Etude des interactions d'échange dans les oxydes multiferroïques RMn₂O₅ / Exchange interactions study in multiferroic oxides RMn₂O₅

Yahia, Ghassen

20 November 2017

Les systèmes multiferroïques magnéto-électriques sont des matériaux multifonctionnels très importants du point de vue des applications dans le domaine de l’électronique ou de la spintronique puisqu’ils présentent simultanément des ordres électriques et magnétiques généralement couplés. Ils peuvent donc répondre à la fois à l’application d’un champ magnétique et d’un champ électrique. L’une des familles de multiferroïques magnéto-électriques les plus étudiées est la série RMn₂O₅ où R est une terre rare. Ma thèse porte sur le rôle de la terre rare sur le caractère multiferroïque et sur les propriétés magnétiques de ces composés. De nombreux travaux ont déjà été publiés mais très peu concernent les composés SmMn₂O₅ et GdMn₂O₅, difficiles à étudier aux neutrons. Pourtant ce sont des composés clés, à la frontière entre des composés à terres rares légères qui ne sont pas multiferroïques et ceux à terres rares lourdes qui le sont. Je me suis donc intéressé à ces composés. Grâce à une étude théorique basée sur une analyse de symétrie et des calculs numériques ab initio tenant compte du fort couplage spin-orbite, nous avons pu prévoir un modèle pour l’ordre magnétique stabilisé dans Sm et Gd. Nous avons en parallèle étudié expérimentalement les structures magnétiques pour ces deux composés par le biais d’une analyse des donnés de diffraction de neutrons sur poudre utilisant des matériaux isotopes de Sm et Gd. Ma thèse a permis d’une part de valider le mécanisme d’échange striction comme origine du couplage magnéto-électrique dans cette série importante de multiferroïques. Elle a permis d’autre part de mettre en évidence l’existence d’une interaction d’échange supplémentaire dans GdMn₂O₅, à l’origine de la forte polarisation électrique dans ce membre de la série. Ces résultats amènent plus de clarté à la compréhension de la multiferroïcité dans ces systèmes. / The magneto-electric multiferroic systems are multifunctional materials very important for applications in the field of electronics or spintronics since they present simultaneously electrical and magnetic orders, which are generally coupled. They can thus respond to both the application of a magnetic field and an electric field. One of the most studied magneto-electric multiferroic families is the RMn₂O₅ series where R is a rare earth. My thesis deals with the role of rare earth on the multiferroic and the magnetic properties of these compounds. Numerous works have already been published, but very few concern the compounds SmMn₂O₅ and GdMn₂O₅, difficult to study with neutrons. Yet these are key compounds, on the border between light rare earth compounds that are not multiferroic and heavy rare earths that are. This explains my interest for these compounds. Using a theoretical study based on a symmetry analysis and numerical calculations ab initio taking into account the strong spin-orbit coupling, we were able to predict a model for the stabilized magnetic order in Sm and Gd. We have experimentally studied the magnetic structures for these two compounds by means of an analysis of the powder neutron diffraction data using Sm and Gd isotopes. On one hand, my thesis allowed to validate the mechanism of exchange striction as origin of the magnetoelectric coupling in this important series of multiferroics. On the other hand, it has made it possible to demonstrate the existence of an additional exchange interaction in GdMn₂O₅, at the origin of the strong electrical polarization in this member of the series. These results provide greater clarity to the understanding of multiferroicity in these systems.

Magnétisme frustré

Multiferroïque

Terre rare

Systèmes fortement corrélés

Effet magnéto-électrique

Frustrated magnetism

Multiferroic

Rare earth

Strongly correlated systems

Magnetoelectric effect

Matériaux multiferroïques : structure, ordres et couplages. Une étude par spectroscopie Raman / Multiferroic materials : structure, multiferroic orders and couplings. A Raman spectroscopy study

Toulouse, Constance

14 June 2016

Les matériaux multiferroïques sont des matériaux dans lesquels des ordres magnétiques, électriques et élastiques peuvent coexister dans une même phase. Ces ordres peuvent être couplés entre eux et l’étude de ces couplages permet de mieux comprendre les mécanismes à l’œuvre dans ces matériaux. Cette thèse porte sur l’étude de différents composés multiferroïques par spectroscopie Raman. Dans la ferrite de bismuth (BiFeO₃), l'effet de la contrainte sur le magnétisme, aussi bien sur les films minces (par contrainte épitaxiale) que le bulk (par pression hydrostatique) est étudié en détail. Cette thèse présente également une étude des excitations hybrides magnéto-électriques (électromagnons) dans les composés de type II à forte polarisation ferroélectrique comme CaMn₇O₁₂ et TbMnO₃. En outre, les modes de phonons ainsi que les excitations de basses énergies ont été étudiés (notamment sous champ magnétique) dans des composés au magnétisme frustré comme h-YMnO₃, h-YbMnO₃ et dans le langasite de fer au niobium. / Multiferroics are materials in which magnetic, electric and elastic orders can coexist in the same phase. These orders can be coupled to each other and their study of high interest to understand the mecanisms at stake in the multiferroic materials. This PhD thesis has been focused on the study of several multiferroic compounds by the mean of Raman spectroscopy. In bismuth ferrite (BiFeO₃), the effect of strain on the magnetic order, both on thin films (epitaxial strain) and single crystals (hydrostatic pressure), has been thoroughly investigated. This thesis also focuses on the study of hybrid magneto-electric excitations (electromagnons) in type II multiferroic compounds with strong ferroelectric polarizations such as CaMn₇O₁₂ and TbMnO₃. Furthermore, phonons modes and of low energy excitations have been measured and studied (especially under magnetic field) in compounds with frustrated magnetic orders such as h-YMnO₃, h-YbMnO₃ and in the niobium iron langasite (Ba₃NbFe₃Si₂O₁₄).

Matériaux multiferroïques

Spectrocopie Raman

Couplage magnéto-électrique

Propriétés structurales

Magnétisme

Cristaux

Ferroélectricité

Multiferroic materials

Raman Spectroscopy

Magnetoelectric coupling

Structure

Magnetism

Crystals

Ferroelectricity