Phénomènes hyperfréquences et nonlinéaires dans les structures actives ferromagnétiques planaires / High frequency and nonlinear phenomena in thin active ferromagnetic planar structures

Ignatov, Yury

29 June 2012

Les récentes découvertes sur les phénomènes hyperfréquences et nonlinéaires dans les structures minces ferromagnétiques actives planaires ont fait émerger un grand nombre de nouvelles études et applications pratiques prometteuses. La conversion de l'énergie magnétoélastique peut être beaucoup plus efficace à proximité de la transition de réorientation de spin (TRS). Les structures minces ferromagnétiques actives planaires fournissent un grand nombre de caractéristiques haute fréquence uniques : par exemple, les conditions pour l’effet Doppler anomal peuvent être satisfaites. Les cristaux magnoniques représentent également un domaine prometteur pour les futures investigations.Dans le présent travail nous avons établi la description théorique de la propagation des ondes hyperfréquences et non-linéaires dans les structures minces ferromagnétiques actives planaires de compositions différentes. Il a été démontré expérimentalement et théoriquement que les vibrations basse fréquence d’un cantilever peuvent être amplifiées quand la résonance ferromagnétique est excitée par un champ électromagnétique HF à proximité de la TRS. En outre, l'effet de la démodulation magnétoélastique peut être complété par un effet magnétoélectrique nonlinéaire. La possibilité de l'apparition de l'effet Doppler anomal lors de la propagation d'une onde de surface magnétostatique dans une structure ferrite-diélectrique-métal, dans une certaine plage de paramètres du système, est démontrée. La dispersion d'une onde magnétostatique de surface se propageant dans un film dont l'épaisseur varie linéairement, et possédant une structure périodique sous la forme de bandes parallèles gravées, a été calculée / Recently discovered investigations on the high frequency and nonlinear phenomena in thin active ferromagnetic planar structures showed a great number of new studies and promising practical applications. The magnetoelastic energy conversion can be much more efficient in the vicinity of spin reorientation transition (SRT). The thin active ferromagnetic planar structures provide a lot of unique high frequency features: for instance, the anomalous Doppler effect conditions can be satisfied. The magnon crystals are also an actual area for the further investigation of the domain.In the present work we derived the theoretical description for the high frequency and non-linear waves propagation in thin planar ferromagnetic structures with different compositions. It was demonstrated experimentally and theoretically that LF vibrations of the cantilever can be amplified when FMR is excited by HF electromagnetic field near SRT. Moreover the magnetoelastic demodulation effect can be supplemented with nonlinear magnetoelectric effect. The possibility of the occurrence of the anomalous Doppler effect during propagation of an MSSW in an FDM structure in a certain range of system parameters is substantiated. The dispersion of a surface magnetostatic wave propagating in a film, whose thickness varies linearly, with a periodic structure in the form of parallel etched strips was calculated. As it was clearly demonstrated these works are of great interest for the new studies and practical applications

Démodulation magnétoélastique

Résonance ferromagnétique

Effet magnétoélectrique non linéaire

Transition de réorientation de spin

Cristaux magnoniques

Ondes magnétostatiques

Effet Doppler anormal

Structures ferrite-diélectrique-métal

Magnetoelastic demodulation

Ferromagnetic resonance

Nonlinear magnetoelectric effect

Spin reorientation transition

Magnon crystals

Magnetostatic waves

Anomalous Doppler effect

Ferrite-dielectric-metal structures

Growth and Studies of Phase Transitions in Multifunctional Perovskite Materials

Yadav, Ruchika

January 2015

Crystal growth and characterization of few multifunctional materials with perovskite (ABX3) structure are discussed in this thesis. Efforts were made to modify the magnetic and electric behaviour of these materials by selective tuning of A, B and X components. Structural, magnetic and dielectric characterization are detailed in various chapters for doped (A and B site) rare-earth manganites and organometallic compounds with different (Chloride or formate) anions. The relevant aspects of crystal structure and its relationship with ordered ground states are discussed in the introductory chapter. A detailed review of prominent theories pertaining to magnetic and ferroelectric ordering in the literature is provided. Growth of various inorganic compounds by solid-state reaction and floating zone method as well as use of solvothermal techniques for growing organometallic compounds are discussed. Material preparation, optimization of crystal growth processes and results of characterization are addressed in various chapters. The effect of Yttrium doping on structural, magnetic and dielectric properties of rare-earth manganites (RMnO3 where R = Nd, Pr) has been investigated. Neutron diffraction studies (Pr compounds) confirm A-type antiferromagnetic structure and fall in transition temperature as the Yttrium doping level increases. Diffraction experiments in conjunction with dc magnetization and ac susceptibility studies reveal magnetic frustration in excess Yttrium dopedcompounds. When mutliglass properties of 50% B-site doped Nd2NiMnO6 were investigated, evidence of re-entrant cluster glass phase was seen probably due to presence of anti-site disorder. The relaxor-like dielectric behaviour arises from crossover of relaxation time in grain and grain boundary regions. Multiferroic behaviour of the organometallic compound (C2H5NH3)2CuCl4 as well as the ferroelectric transition were investigated in detail. The role of Hydrogen bond ordering in driving structural transitions is elucidated by low temperature dielectric and Raman studies in (C2H5NH3)2CdCl4. It was found possible to tune the magnetic and ferroelectric properties in metal formate compounds (general formula AB(HCOO)3) by selectively choosing organic cations [(CH3)2NH2+; C(NH3)3+] and transition metal ion [B = Mn, Co and Cu]. The nature of magnetic ordering and transition temperature could be altered by the transition metal ion. The effect of reorientation of organic cations which leads to ferroelectric nature is discussed using dielectric and pyroelectric data. Significant results are summarized in the chapter outlining general conclusions. Future prospects of work based on these observations are also provided. The conclusions are corroborated by detailed analysis of experimental data.

Magnetoelectric Effect

Multiferroics

Crystal Growth

Phase Transitions

Perovskite Materials

Rare-Earth Manganites

Ferroelectricity

Dielectrics

Magnetism

Metal-Organic Frameworks

Hybrid Organic-Inorganic Compounds

Multiferroicity

FerroelectricMetal Organic Frameworks

(C2H5NH3)2CdCl4

Pr1−xYxMnO3

Nd2NiMnO6

Nd1−xYxMnO3

(CH3)2NH2Co(HCOO)3

C(NH2)3Cu(HCOO)3

Nd2NiMnO6

Physics

Materiais e técnicas para nanoestruturas magnetoelétricas compósitas / Materials and techniques for composite magnetoelectric nanostructures

Mori, Thiago José de Almeida

19 December 2014

Conselho Nacional de Desenvolvimento Científico e Tecnológico / Hybrid nanostructures which integrate two or more technologically interesting physical properties are fundamental for developing new generations of electronic devices. Exhibiting at least two coupled ferroic orders, multiferroics are an outstanding class of multifunctional materials. Compounds which present coupling between ferromagnetism and ferroelectricity are specially interesting. Although natural multiferroics are rarely found, the possibility of obtaining strain-mediated magnetoelectric coupling in composite structures, by integrating magnetostrictive and piezoelectric layers, paves the way to control electric properties by applying magnetic field or to the electric control of magnetism. Nevertheless, most scientific efforts have been on monophasic compounds or bulk composites. Considering the incorporation of magnetoelectric nanostructures in devices, expanding the scope of the magnetoelectric effect and targetting it to different kinds of applications is needed. Besides new characterization techniques, seeking new alternative materials to the lead-based piezoelectrics or oxide-based magnetostrictives is necessary. Recently, a few works using semiconductors such as ZnO and AlN, or amorphous magnetic alloys such as those based on Co, Fe and Ni, have been reported. In spite of not presenting remarkable piezoelectric and magnetostrictive effects, the features of such materials are promising for high frequency applications, for instance. Considering these issues, four independent surveys are presented. Firstly, the origin of the coupling, latest advances and current scenario of the field are reviewed. Then magnetostriction measurements in thin films are addressed by employing a direct technique based on the cantilever-capacitance method. The goals are to study magnetoelastic properties of some materials whose magnetostriction are not found very often in literature, and to check the reliability of this technique for investigating thin films. In this sense, measurements of some amorphous magnetic alloys mainly based on Co, Fe and Ni are performed. Most samples presents larger magnetoelastic response for magnetic field applied along the magnetization easy axis, as opposed to the theoretically expected. Two investigations on aluminum nitride thin films are reported. Firstly, the growth of AlN films onto several different substrates and buffer layers is studied. Films grown onto glass and polyimide show excellent structural properties for eletromechanical systems and flexible electronics applications. Samples with low residual stress on silicon substrates, suitable for incorporating in existing technologies, are obtained. Secondly, bilayers composed by AlN and ferromagnetic films are investigated. In addition to the structural and morphological properties of the AlN films which are checked, the magnetic characterization of the structures also contributes to design multilayers for exploring the magnetoelectric effect. Finally, problems involving electric fields in scanning probe microscopies are adressed. Surface images of AlN piezoelectric films are systematically acquired. Among other major observations, the possibility of getting reliable piezoresponse images of strongly polarized areas as well as of visualizing ferroelastic domains, is demonstrated. Furthermore, a new microscopy for investigating a sample s ferro and piezoelectric properties is proposed, exploring the direct piezoelectric effect. By utilizing acoustic excitation and electrical detection, the potency of this technique is illustrated with measurements on quartz and AlN surfaces. / Nanoestruturas híbridas, integrando duas ou mais propriedades físicas de grande interesse tecnológico, são fundamentais para o desenvolvimento de novas gerações de dispositivos eletrônicos. Uma classe interessante de materiais multifuncionais são os multiferróicos, que exibem pelo menos duas ordens ferróicas acopladas. Dentre eles, os que apresentam acoplamento entre ferromagnetismo e ferroeletricidade despertam interesse especial. Apesar de serem raros de ocorrer naturalmente, a possibilidade de gerar efeito magnetoelétrico em estruturas compósitas, intermediado pela deformação elástica entre camadas magnetostrictivas e piezoelétricas, abre caminho para que seja possível controlar propriedades elétricas aplicando-se campo magnético, ou propriedades magnéticas aplicando-se campo elétrico. Todavia, a maior parte das pesquisas atuais ainda envolve compostos monofásicos ou compósitos em forma massiva. Tendo em vista a incorporação de nanoestruturas magnetoelétricas em dispositivos, é fundamental ampliar a abrangência do efeito magnetoelétrico e direcioná-lo para diferentes tipos de aplicações. Para isto, além de novas técnicas de caracterização, é necessário buscar-se materiais alternativos aos tradicionais piezoelétricos baseados em chumbo e magnetostrictivos baseados em óxidos. Recentemente tem-se encontrado trabalhos pontuais onde são utilizados piezoelétricos semicondutores como ZnO e AlN, e ligas magnéticas amorfas como as baseadas em Co, Fe e Ni. Mesmo sem apresentar efeitos piezoelétrico e magnetostrictivo com magnitudes notáveis, as características destes materiais são promissoras para aplicações envolvendo altas frequências, por exemplo. Neste necessário, são apresentados quatro estudos independentes entre si. Primeiramente, é realizada uma revisão sobre a origem do acoplamento, os últimos avanços e o panorama atual das pesquisas na área. Em seguida, através de uma técnica direta baseada no método do cantiléver-capacitância, aborda-se o problema das medidas de magnetostricção em amostras na forma de filmes finos. Os objetivos são estudar as propriedades magnetoelásticas em alguns materiais que não são frequentemente abordados pela literatura, e avaliar a potencialidade da técnica para a análise de filmes finos. Para isto, são realizadas medidas principalmente em ligas ferromagnéticas amorfas baseadas em Co, Fe e Ni. Para a maioria das amostras analisadas, a resposta magnetoelástica é maior quando o campo magnético é aplicado na direção do eixo de fácil magnetização, de forma contrária à esperada teoricamente. São apresentadas duas investigações envolvendo filmes finos de nitreto de alumínio. Primeiro é estudado o crescimento de filmes de AlN sobre vários substratos e camadas semente. Filmes crescidos sobre vidro e poliimida apresentam excelentes propriedades estruturais para aplicações em sistemas eletromecânicos e eletrônica flexível. Amostras obtidas com baixos valores de tensão residual, sobre substratos de silício, são interessantes para incorporação em tecnologias existentes. Segundo, são investigadas bicamadas de AlN com filmes ferromagnéticos. Além das propriedades estruturais e morfológicas dos filmes de AlN, a análise das características magnéticas das estruturas contribui para o design de multicamadas que exploram o efeito magnetoelétrico. Finalmente, são abordados problemas em medidas de microscopias de varredura por sonda envolvendo campos elétricos. Imagens da superfície de filmes piezoelétricos de AlN foram coletadas sistematicamente. Entre outras observações importantes, demonstra-se que é possível adquirir imagens confiáveis de piezo-resposta em regiões fortemente polarizadas, e visualizar a formação de domínios ferroelásticos. Também é proposta uma nova técnica de microscopia, para investigar as propriedades ferro e piezoelétricas de uma amostra, explorando o efeito piezoelétrico direto. Utilizando excitação acústica e detecção elétrica, o potencial da nova técnica é demonstrado com imagens de superfícies cristalinas de quartzo e AlN.

Efeito magnetoelétrico

Nanoestruturas compósitas

Magnetostricção

Método do cantilévercapacitância

Ligas ferromagnéticas amorfas

Nitreto de alumínio

Microscopia de varredura por sonda

Microscopia de piezo-resposta

Magnetoelectric effect

Composite nanostructures

Magnetostriction

Cantilever-capacitance method

Amorphous ferromagnetic alloys

Aluminum nitride

Scanning probe microscopy

Piezoresponse force microscopy

Direct piezoelectric effect microscopy

CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA

Theoretical investigation of size effects in multiferroic nanoparticles

Allen, Marc Alexander

05 August 2020

Over the last two decades, great progress has been made in the understanding of multiferroic materials, ones where multiple long-range orders simultaneously exist. However, much of the research has focused on bulk systems. If these materials are to be incorporated into devices, they would not be in bulk form, but would be miniaturized, such as in nanoparticle form. Accordingly, a better understanding of multiferroic nanoparticles is necessary. This manuscript examines the multiferroic phase diagram of multiferroic nanoparticles related to system size and surface-induced magnetic anisotropy. There is a particular focus on bismuth ferrite, the room-temperature antiferromagnetic-ferroelectric multiferroic. Theoretical results will be presented which show that at certain sizes, a bistability develops in the cycloidal wavevector. This implies bistability in the ferroelectric and magnetic moments of the nanoparticles. This novel magnetoelectric bistability may be of use in the creation of an electrically-written, magnetically-read memory element. / Graduate

bismuth ferrite

bfo

nanoparticle

nanomagnetism

multiferroics

optimization

magnetism

ferroelectric

bistability

anisotropy

surface anisotropy

weak ferromagnetism

antiferromagnetism

Dzyaloshinskii-Moriya interaction

cycloid

numerical methods

condensed matter

solid state physics

magnetoelectric effect

room-temperature multiferroic

superexchange

magnetic memory

spin canting

g-type antiferromagnetism

Heisenberg Hamiltonian

Nelder-Mead

L-BFGS-B

mathematica

python

ferroelectricity

perovskite

antiferromagnet

bifeo3

rhombohedral

pseudocubic

r3c

trigonal

physics

magnetic

memory

electrically-written memory

curie temperature

néel temperature

materials science