Estudo da correlação entre a razão de transferência de magnetização e a volumetria em pacientes com lesão axonal traumática / Correlation between the magnetization transfer ratio and brain volume in patients with traumatic axonal injury

Macruz, Fabíola Bezerra de Carvalho

08 February 2019

Introdução: A lesão axonal traumática (LAT) ou lesão axonal difusa (LAD) esta presente em grande parte dos traumatismos crânio-encefálicos (TCE), sendo importante causa de mortalidade e morbidade das suas vítimas. A LAT dispara uma sequência de mudanças neurodegenerativas encefálicas que são, paradoxalmente, acompanhadas por recuperação cognitiva. Objetivo: Avaliar quantitativamente a LAT, através da razão de transferência de magnetização (RTM) e de medidas volumétricas para caracterizar a evolução temporoespacial das mudanças macroscópicas e microscópicas e investigar possível correlação entre elas, auxiliando no entendimento da sua fisiopatologia. Este estudo ainda investigou correlação entre atrofia e dano axonal/mielínico e a evolução funcional. Métodos: Imagens 3D-T1, 3DGE (PRESTO) e de transferência de magnetização (ITM) foram obtidas de 26 pacientes vítimas de TCE moderado e grave e de 26 controles, de idade e sexo semelhantes. Os pacientes foram submetidos a RM com 2 (fase aguda tardia/subaguda), 6 (crônica precoce) e 12 (crônica tardia) meses do TCE. A RM foi realizada nos controles em apenas uma única ocasião. Através de métodos automatizados, calculou-se o volume da substancia cinzenta (SC), da substancia branca (SB) e do encéfalo total (ET), ajustando-os pelo volume intracraniano. A partir de histogramas da RTM obtidos das mesmas regiões, calculou-se a média e os percentis 25, 50 e 75% da RTM. As imagens PRESTO foram usadas na exclusão dos focos hemorrágicos da análise da RTM, nos pacientes. A evolução funcional foi medida pela escala prognostica de Glasgow (EPG), realizada um ano após o TCE. Resultados: A RTM media e o volume foram significativamente diferentes nos pacientes e nos controles. Os pacientes apresentaram RTM media maior (p < 0,05) e volume menor na SC e ET, desde o primeiro exame (fase aguda tardia/subaguda precoce). Na SB, valores menores tanto da RTM media (p=0,02) quanto do volume (p=0,009) foram observados nos pacientes apenas no terceiro exame (fase crônica tardia). Redução progressiva da RTM media dos pacientes foi observada em todos os compartimentos, estimada em 1,14% na SC, 1,38% na SB e 1,40% no ET durante todo o estudo. Houve também redução volumétrica gradual da SB e do ET, com taxa de atrofia total de 3,20% e 1,50%, respectivamente. Não houve relação entre redução da RTM media e atrofia. Nenhum dos parâmetros mostrou valor prognostico nas fases subaguda ou crônica precoce. Conclusões: A LAT resulta numa rarefação axonal/mielínica e redução volumétrica progressiva do tecido encefálico, que se perpetua por até um ano do trauma. As mudanças são mais expressivas e prolongada na SB. A redução do volume e da RTM media se mostraram independentes na LAT. Isso sugere que os dois parâmetros reflitam aspectos complementares da fisiopatologia da LAT, em níveis micro e macroestrutural / Introduction: Traumatic axonal injury (TAI) or diffuse axonal injury (DAI) is a frequent component of traumatic brain injury (TBI) and a major cause of mortality and morbidity in this population. It triggers a sequence of degenerative changes in the brain, that are paradoxically accompanied by cognitive recovery. Purposes: The present study used magnetization transfer ratio (MTR) and volumetric data to appreciate the spatiotemporal evolution of macroscopic and microscopic changes and investigate possible correlation between them, enhancing the knowledge about its pathophysiology. It also investigated correlation between atrophy and axonal/myelin damage and functional outcome. Methods: Volumetric T1-weighted, 3DGE (PRESTO) and magnetization transfer images (MTI) were obtained from 26 patients who experienced moderate to severe TBI and 26 age- and sex-matched controls. Patients were scanned at 2 (late acute/subacute stage), 6 (early chronic) and 12 months (late chronic) postinjury and controls, only once. Whole brain (WB), gray matter (GM) and white matter (WM) volumes were measured using automated technique and adjusted for intracranial volume. Histogram analysis was performed in the same regions, with calculation of the mean MTR and its 25, 50 and 75% percentiles. The PRESTO images were used to exclude the small lesions from the MTR analysis in the patients. Functional outcome was assessed 12 months after injury using the Glasgow Outcome Scale (GOS). Results: Mean MTR and volume were significantly different between patients and controls. Patients presented higher mean MTR values (p < 0,05) and smaller volume (p < 0,05) in the GM and WB, as of the first exam (late acute/subacute stage). In the WM, reduction of both, the mean MTR (p=.02) and volume (p=.009), was observed only in their third exam (late chronic stage). Progressive decrease of patients\' mean MTR was observed in all compartments, with rates of 1.14% for the GM, 1.38% for the WM and 1.40% for the WB across the study. Continuing reduction of the WM and WB volume was also observed, with total atrophy rate of 3.20% and 1.50%, respectively. No correlation between mean MT and the volumetric changes was found. None of the parameters showed prognostic value during the subacute and early chronic stages. Conclusions: TAI results in a progressive axonal/myelinic rarefaction and volumetric brain reduction that continues until a year postinjury. The changes are greater and lasts longer in the WM. The reduction in the volume and mean MTR were independent between them in TAI. This suggests that the two parameters reflect complementary aspects of the TAI pathologic lesion at macro and microstructural levels

Atrofia

Atrophy

Axonal-myelinic damage

Brain injuries traumatic

Craniocerebral trauma

Dano axonal-mielínico

Diagnostic imaging

Diagnóstico por imagem

Diffuse axonal injury

Lesão axonal difusa

Lesões encefálicas traumáticas

Magnetization transfer imaging

Traumatismos craniocerebrais

Indução ótica de magnetização em semicondutores magnéticos / Optically induced magnetization in magnetic semiconductors

Moraes, Flávio Campopiano Dias de

29 September 2017

Nesta tese, analisamos dois sistemas de semicondutores magnéticos: um semicondutor magnético cristalino de EuTe e uma heteroestrutura formada por um poço quântico de GaAs/AlGaAs ao lado uma barreira tipo delta de Mn, que, ao difundir-se, forma o semicondutor magnético diluído de (Ga,Mn)As. Nossos estudos foram focados na possibilidade de manipularmos oticamente a orientação magnética de ambos os sistemas. No semicondutor magnético de EuTe, a indução de magnetização se dá pela formação de polarons magnéticos ao redor de elétrons fotoexcitados. Para o estudo dos polarons, um modelo teórico elaborado foi adaptado para a construção de um sistema computacional baseado no método de Monte Carlo. Essa sistema permitiu o cálculo do momento magnético e do raio do polaron em temperaturas finitas, muito acima da temperatura de Néel. O modelo foi elaborado para reproduzir tanto as propriedades do EuTe sem o polaron (temperatura de Néel e campo crítico), quanto o deslocamento da linha de fotoluminescência devido a formação do polaron. Além do desenvolvimento do próprio método computacional, que pode ser utilizado para estudar outros sistemas, o conhecimento adquirido com o estudo do EuTe serviu como base para o estudo de um sistema mais complexo, que é a heteroestrutura de GaAs/AlGaAs + dMn. O estudo da heteroestrutura de GaAs/AlGaAs + dMn foi feito em cima de medidas experimentais de rotação de Kerr com resolução temporal. O sistema de medição construído permite, também, medidas de rotação de Kerr com resolução espacial, que servem para o estudo de transporte e hélice de spin em semicondutores, e está detalhadamente descrito em um dos capítulo desta tese. Na amostra estudada, o controle da magnetização dos íons de Mn é feito através da interação de troca com o elétron fotoexcitado no poço quântico. Os resultados obtidos das medidas de rotação de Kerr mostram uma frequência de precessão dependente do tempo, que revela a existência de dois processos com dinâmicas diferentes: uma primeira orientação do spin dos íons de Mn devido à polarização do par elétron-buraco no poço quântico, seguida por um realinhamento desses spins com o campo magnético externo, a partir do momento em que a coerência dos spins dos buracos desaparece. Esse resultado sugere que a interação entre os elétrons fotoexcitados e os íons de Mn ocorre por intermédio dos buracos fotoexcitados, ao contrário do que havia sido proposto em estudos anteriores de estruturas similares, mas de acordo com o modelo de interação sp-d, utilizado para explicar o ferromagnetismo do (Ga,Mn)As. / In this thesis we analyzed two magnetic semiconductor systems: one intrinsic magnetic semiconductor crystal of EuTe and one GaAs-based heterostructure with a GaAs/AlGaAs quantum well close to delta-type Mn barrier, that forms a diluted magnetic semiconductor of (Ga,Mn)As after diffusion. Our studies on both systems were focused on the possibility of optical manipulation of magnetic order. In EuTe pure semiconductor, the magnetization control occurs due to de formation od magnetic polarons around photo-excited electrons. To study magnetic polarons we adapted a theoretical model to build a computer simulation system based on Monte Carlo\'s method. This system allowed us to calculate the magnetic moment and radius of the polaron at finite temperatures fair above Néel Temperature. The computational model was tested to reproduce EuTe properties without polarons (Néel Temperature and critical magnetic field) and with polarons (photoluminescence line shift). Beside the development of this computational model, that can be used to study other systems, the knowledge acquired during the studies on EuTe helped us to better understand the more complex system of the GaAs/AlGaAs +dMn heterostructure. The studies about the GaAs/AlGaAs + dMn heterostructure were based on experimental measurements of time-resolved Kerr rotation. The measurement system we built also allows us to perform spatial-resolved Kerr rotation measurements to study spin transport and spin helix on semiconductors and it is described in details in one chapter of this thesis. The optical manipulation of Mn ions magnetization on the studied sample is consequence of the exchange interaction with the photoexcited electron inside the quantum well. The results of Kerr rotation measurements show a time-dependent precession frequency that reveals the existence of two process with distinct dynamics: the initial orientation of Mn ions spins with the photoexcited electron-hole pair, followed by the realignment of these spins with the external magnetic field, as soon as the photoexcited hole spins loose its coherence. These results indicate that the exchange interaction between the photoexcited electron inside the quantum well and the Mn ions is mediated by the photoexcited holes, in opposition of what was being proposed in previous studies of similar structures, but in agreement with the sp-d model, used to explain the (Ga,Mn)As ferromagnetism.

(Ga,Mn)As

(Ga,Mn)As

EuTe

EuTe

exchange interaction

indução de magnetização

interação de troca

magnetic polaron

magnetization control

modelo de Zener

polaron magnético

rotação de Kerr

spatial-resolved Kerr rotation

TRKR

Zeners model

Dynamique de l'aimantation assistée par un champ électrique dans des dispositifs à base de (Ga,Mn)As / Electric field induced magnetization dynamic in (Ga,Mn)As based devices

Balestrière, Pierrick

25 January 2011

Ce travail de thèse a été consacré à l'étude à la fois théorique et expérimentale de la dynamique de l'aimantation assistée par un champ électrique dans un dispositif à base de (Ga,Mn)As. Une couche de (Ga,Mn)As, dont l’anisotropie magnétique est complexe, est un matériau de choix pour la manipulation de l’aimantation par un champ électrique.J’ai présenté une stratégie de retournement précessionnel de l'aimantation qui tire partie de la réduction transitoire de l'anisotropie cubique provoquée par une courte impulsion de champ électrique. A l’aide d’un modèle macrospin, j’ai démontré notamment qu'une impulsion de champ électrique de quelques ns de durée est suffisante pour basculer l'aimantation entre deux positions d'équilibres.L'aspect expérimental est basé sur l'utilisation d'une jonction p-n tout semi-conducteur dont la région dopée p est formée par une couche mince de (Ga,Mn)As. La déplétion des porteurs de charge dans le canal semi-conducteur provoquée par l'application d'un train d'impulsions de tension de courte durée induit une forte diminution du champ d'anisotropie cubique. L'étude expérimentale du renversement de l'aimantation en champ magnétique a conduit à la mise en évidence d'un retournement de l'aimantation via la nucléation et la propagation de parois et d’une distribution large des champs de piégeage. L'inhomogénéité magnétique au sein de la couche de (Ga,Mn)As a empêché l'observation d'une résonance ferromagnétique induite par un champ électrique. Néanmoins, des mesures de retournement avec une ou plusieurs impulsions de tension de grille ont permis de proposer un processus de renversement de l'aimantation induit par un champ électrique. / This work has been devoted to the study of both theoretical and experimental electric field induced magnetization dynamics in a (Ga,Mn)As based device. A layer of (Ga,Mn)As, whose magnetic anisotropy is complex, is of particular interest for magnetization manipulation by electric fields.I proposed a scheme for the precessional switching of the magnetization using cubic anisotropy field reduction triggered by electric field pulse. Using a model macrospin, I demonstrated that a ns-pulse is sufficient to switch the magnetization between two equilibrium positions.An all-semiconductor epitaxial p-n junction based on low-doped (Ga,Mn)As was fabricated. Gating effects triggered by low voltage pulses induced a strong decrease of the cubic anisotropy field. I demonstrated that magnetization reversal is dominated by the nucleation and the propagation of domain walls. The distribution of pinning fields was found to be broad. Due to a magnetic inhomogeneity of the (Ga,Mn)As layer, it was not possible to observe any ferromagnetic resonance induced by an electric field. However, I proposed a magnetization reversal scenario based on single or multiple gate voltage pulses measurements

(Ga,Mn)As

Retournement précessionnel

Dynamique aimantation

Jonction p-n

Champ électrique

Domaines magnétiques

Cycle d’hystérésis

(Ga,Mn)As

Precessional switching

Magnetization dynamic

P-n junction

Electric field

Magnetic domains

Hysteresis curve

Propriétés statiques et dynamiques des chaînes aimants / Static and dynamic properties of Single Chain Magnets

Pianet, Vivien-Maxime

02 December 2014

Dans le domaine du stockage de l'information, la miniaturisation de l'unité magnétique portant l'information est un enjeu capital. Ainsi, la découverte de molécules possédant des propriétés de relaxation lente de leur aimantation, comparables à celles des aimants classiques, constitue une avancée majeure suscitant l'espoir de pouvoir un jour stocker l'information à l'échelle moléculaire.Cette thèse a pour but d'étudier les propriétés magnétiques des chaînes aimants. Ces chaînes sont constituées d'unités magnétiques liées par des interactions magnétiques au sein d'un réseau unidimensionnel. Au delà de leurs potentielles applications, les chaînes aimants sont parfaitement adaptées à l'étude fondamentale des chaînes de spins. Le premier chapitre de ce manuscrit constitue un rappel des propriétés statiques et dynamiques des chaînes aimants connues à ce jour. Le deuxième chapitre décrit les propriétés statiques des parois séparant les différents domaines d'aimantation dans des chaînes de spins de topologies magnétiques variées. Le troisième chapitre de ce manuscrit décrit les propriétés dynamiques des chaînes de spins d'Ising. Bien que seul le modèle de Glauber soit utilisé dans la littérature associée aux chaînes aimants, il existe une infinité de modèles dynamiques d'Ising.Grâce à l'étude détaillée de trois modèles, il est montré dans ce chapitre que l'application d'un champ magnétique permet de révéler différentes dynamiques de relaxation de l'aimantation pour chacun des modèles considérés. Ces résultats permettent enfin de proposer deux protocoles expérimentaux à même de déterminer le modèle dynamique le plus adapté à l'étude des chaînes aimants. / The size reduction of magnetic units able to store information is an important issue for the design of high-density data storage devices. The discovery of molecules that show slow relaxation of their magnetization, similar to classical magnets, is a great breakthrough in terms of molecular scale information storage. The work presented in this thesis is devoted to the study of the magnetic properties of Single Chain Magnets. Single Chain Magnets can be viewed as a one-dimensional assembly of anisotropic magnetic units linked by magnetic interactions. Beyond their potential applications, Single Chain Magnets are interesting prototypes for the fundamental study of spin chains. The first chapter of this manuscript summarizes some known static and dynamic properties of Single Chain Magnets. Chapter II is devoted to the static properties of domain walls, which link the magnetic domains in spin chains, considering various magnetic topologies. Chapter III is dedicated to the dynamic properties of Ising spin chains. In the Single Chain Magnet literature, the Glauber model is used to describe the dynamic properties of such spin chains. However, there exists an infinite number of dynamic Ising models. In this chapter, three dynamic models are studied in detail. We show that the presence of a magnetic field allows us to discern different magnetization relaxation behaviors associated with each dynamic model. These results allow us to establish two experimental protocols in order to determine the most suitable dynamic model to describe the properties of Single Chain Magnets.

Magnétisme moléculaire

Simulation Monte Carlos

Relaxation lente de l’aimantation

Dynamique stochastique

Modèles d’Ising dynamiques

Paroi

Chaîne aimant

Molecular magnetism

Monte Carlo simulations

Magnetization slow relaxation

Stochastical dynamics

Dynamic Ising models

Domain wall

Single chain magnets

Study of the magnetotransport behavior and electrical properties in the colossal magnetoresistance materials La0.7-xLnxPb0.3Mn1-yMeyO3 (Ln=Pr, Nd and Y, Me=Fe and Co)

Young, San-Lin

08 July 2002

The hole-doped perovskite manganese oxide such as Ln1-xAxMnO3 (Ln = La, Nd, Pr, and A = Ca, Sr, Ba, Pb) is one of the most studied topics in the recent years due to the observation of colossal magnetoresistance (CMR). Basically, LaMnO3 has an almost insulating behavior and on antiferromagnetic arrangement. By substituting a divalent cation (A2+) in place of La3+, LaMnO3 can be driven into metallic and ferromagnetic state. Mixed valence of Mn 3+ / Mn4+ is needed for both metallic behavior and ferromagnetism in these materials. The CMR characteristic occurs in the ferromagnetic state. A systematic investigation of the structural, magnetic and electrical properties in the perovskite colossal magnetoresistance materials La0.7-xLnxPb0.3Mn1-yMeyO3 (Ln=Pr, Nd and Y, Me=Fe and Co) has presented in this thesis. By subatituting Nd, Pr, Y for the La and Co, Fe for the Mn, the substitution effects on the crystallographic deformation, magnetotransport behavior and electrical properties in these compounds have been studied. According to the results of this research, crystallographic distortion is induced by the substitution of smaller ions, Pr or Nd, onto the La-site. Powder $x$-ray diffraction patterns show a crystallographic transition from rhombohedral symmetry (R-3c) to orthorhombic (Pbnm) crystal structure as the doping content is increased. The increase of deformation from R-3c to Pbnm decreases the bond angle of Mn3+¡ÐO2-¡ÐMn4+ , increases the cant of Mn spin, weakens the double-exchange interaction and results in decrease of ferromagnetism, low ferromagnetic transition temperature Tc, eg electron bandwidth and conductivity. However, the great quantity of decrease in resistivity by an external field leads to the increase in the magnetoresistance ratio. We also find that the increase of saturation magnetization results from the contribution of magnetic ion of Pr or Nd. In addition. in contrast to substitution La by magnetic ion of Pr and Nd, the saturation magnetization is decreased as Y content is increased. The zero-field-cool (ZFC) and field-cool (FC) magnetic measurements indicate that the range of spin ordering for Y one is shorter than Pr one or Nd one with the same doping content. It is because of the small ionic radius of Y, which results in larger distortion, increases the bond angle of Mn3+¡ÐO2-¡ÐMn4+, and corresponds low ferromagnetic transition temperature. The distortion induced by Mn-site substitution is not obvious due to the similar radius of Mn, Co and Fe. Powder x-ray diffraction patterns show a single phase of rhombohedral symmetry (R-3c) for Co doped ststem and a slight crystallographic transition from rhombohedral (R-3c) to orthorhombic (Pbnm) symmetry for Fe doped system. Values of temperature dependence of magnetization indicate that the ferromagnetic double-exchange interaction is gradually substituted by the superexchange interaction. The ZFC-FC curves also indicate that long-range spin ordering is progressively substituted by the short-range spin ordering. The substitution of Mn by Co and Fe supresses the double-exchange interaction, decreases the ferromagnetism and the ferromagnetic transition temperature. Due to the synthesis of the substitution of Nd, Pr, Y for La and Co, Fe for Mn, the mechanism of substitution effects are proved different. The substitution of Nd, Pr and Y for La distorts the crystal, decreases the Mn3+¡ÐO2-¡ÐMn4+ bond angle, and results in the transition of properties, while the substitution of Co and Fe for Mn decrease the percentage of ferromagnetic Mn3+¡ÐO2-¡ÐMn4+. The purpose of this thesis is to clear up the role functions of all elements in these compounds and properties of these compounds. Based on the knowledge of these compounds, it would be helpful to control the physical mechanism and improve the characteristics on preparing their thin film devices.

field-cooling

zero-field-cooling

long range spin ordering

short range spin ordering

resistivity

ferromagnetic transition temperature

antiferromagnetic

spi nordering

ferromagnetic

superexchange interaction

magnetoresistance ratio

saturation magnetization

perovskite

rhombohedral

orthorhombic

colossal magnetoresistance

double-exchange interaction

Magnetization, Magnetotransport And Electron Magnetic Resonance Studies Of Certain Nanoscale Manganites

Rao, S Srinivasa

08 1900

Perovskite rare-earth manganites of the form R1-xAxMnO3 (R – rare earth ion or Bi, A – Ca,Sr) have drawn an overwhelming research interest during the last few years owing to their extraordinary physical properties. Some of the interesting phenomena exhibited by the manganites are (a) colossal magneotresistance (CMR) (b) charge, orbital and spin ordering and (c) phase separation at nano and micron scale. The manganites are strongly correlated systems in which the charge, spin and orbital degrees of freedom are coupled. The properties of these materials are sensitive functions of external stimuli such as the doping, temperature and pressure [1-5] and have been extensively studied both experimentally and theoretically on single crystal, bulk polycrystalline and thin film forms of the samples [6-9]. Recently attention has been drawn towards the properties of nanoscale manganites. The nanoscale materials are expected to behave quite differently from extended solids due to quantum confinement effects and high surface/volume ratio. Nanoscale CMR manganites have been fabricated using diverse methods in the form of particles, wires, tubes and various other forms by different groups. It has been shown that the properties of CMR manganites can be tuned by reducing the particle size down to nanometer range and by changing the morphology [10-14]. The physical properties of antiferromagnetic insulating charge ordered manganites have been well investigated by using numerous experimental techniques on bulk solids. It is known that the charge ordered (CO) phase is ‘melted’ resulting in a ferromagnetic, metallic phase on application of high magnetic fields, electric fields, impurity ion doping, high energetic ion irradiation and by pressure [15-17]. However, no attempts have been made on the fabrication and the physical property investigations on nanoscale charge ordered manganites. Hence, we have undertaken to study the properties of charge ordered manganites prepared at nanoscale using various experimental probes. In this thesis we present the results on magnetization, magnetotransport and Electron Magnetic Resonance (EMR) (electron paramagnetic resonance in the paramagnetic phase and ferromagnetic resonance in the ferromagnetic phase) studies of the following nanoscale compounds and compare the properties with those of their bulk counterparts; (a) highly robust antiferromagnetic insulating CE –type charge ordered manganite Pr0.5Ca0.5MnO3 (PCMO) (b) highly robust antiferromagnetic insulating CE- type charge ordered manganite Nd0.5Ca0.5MnO3 (NCMO) (c) moderately robust A-type charge ordered manganite Pr0.5Sr0.5MnO3 (PSMO) (d) highly robust insulating anti-ferromagnetic charge ordered manganites Bi0.5Ca0.5MnO3 (BCMO) and Bi0.5Sr0.5MnO3 (BSMO) and (e) a CMR manganite Pr0.7Pb0.3MnO3 (PPMO). Chapter 1 of the thesis contains a brief introduction to the general features of manganites describing various interesting phenomena and the interactions underlying them. Further, we have written a detailed review on the properties of nanometric CMR manganites of various sizes and shapes. In this chapter, we have also described the experimental methodology and the analysis procedure adopted in this work Chapter 2 reports the fabrication of nanowires and nanoparticles of Pr0.5Ca0.5MnO3 (PCMO) and the results obtained from magnetization, magnetotransport and electron magnetic resonance measurements performed on nanoscale PCMO along with their comparison with those of the bulk sample. Here, the nanowires of PCMO were prepared by hydrothermal method and the nanoparticles of mean sizes 10, 20 and 40 nm were prepared by polymer assisted sol-gel method. Solid state reaction method was used to prepare the micron sized PCMO bulk material. Different techniques like XRD, TEM, EDAX and ICPAES have been used to characterize the samples. The novel result of the present investigation is the weakening of charge order and switch over from the anti-ferromagnetic phase to ferromagnetic phase in PCMO nanowires [18]. In addition, the charge order is seem to have completely suppressed in 10 nm PCMO nanoparticles as observed from the magnetization measurements. These results are particularly very significant as one needs magnetic fields of ~ 27 T to melt the charge ordered phase in PCMO. Size induced insulator-metal transition TM-I is observed in nanoscale PCMO at low temperatures accompanied by ferromagnetism. CMR of 99.7% is obtained at TM-I and at a field of 11 T. EMR studies have confirmed the presence of ferromagnetic phase at low temperatures. Temperature dependent EMR line width and intensity have shown the presence of CO phase in PCMO10 though static magnetization measurements have shown the absence of CO phase. It is found that the EMR linewidth increases with the decrease of particle size. Chapter 3 reports the fabrication of nanoparticles of Nd0.5Ca0.5MnO3 (NCMO) and the results obtained from magnetization, magnetotransport and electron magnetic resonance measurements performed on nanoscale NCMO along with their comparison with those of bulk NCMO. The nanoparticles of NCMO of mean sizes 5, 20 and 40 nm were prepared by polymer assisted sol-gel method. Solid state reaction method was used to prepare the micron sized NCMO bulk material. Different techniques like XRD, TEM, EDAX and ICPAES have been used to characterize the samples. A striking result of this particular investigation is the complete suppression of charge ordered phase in 5 and 20 nm NCMO nanoparticles as observed from the magnetization measurements [19]. Size induced insulator-metal transition TM-I is observed in nanoscale NCMO at low temperatures accompanied by ferromagnetism in accordance with Zener double exchange meachanism. CMR of 99.7% is obtained at TM-I and at a field of 11 T. EMR studies have confirmed the presence of ferromagnetic phase at low temperatures. Temperature dependent EMR line width and intensity have shown the presence of residual CO fluctuations in NCMO5 though the static magnetization measurements have shown the absence of CO phase. It is found that the EMR linewidth increases with the decrease of particle size. Low temperature X-ray diffraction measurements on NCMO20 indicate the absence of CO phase. But the preliminary results obtained from the optical spectroscopy measurements indicate the evidence for the presence of CO phase. In Chapter 4, we report the investigations on the nanoscale PSMO. PSMO nanoparticles of sizes 20, 40 and 60 nm are prepared by polymer precursor sol-gel method. PSMO nanowires of diameter 50 nm and lengths of a few microns have been prepared by hydrothermal method. The bulk polycrystalline PSMO is obtained by crushing the single crystal of the same prepared by float zone method. Various techniques like XRD, TEM, VSM, transport measurements and EMR spectroscopy have been employed to characterize and to study the size dependent magnetic, transport and electron magnetic resonance properties and to compare them with those of the bulk. Our results show that there is a disappearance of anti-ferromagnetic charge ordering phase and the appearance of a ferromagnetic phase at low temperatures in all PSMO nanoparticles and nanowires. Metal like behaviour is observed in the size induced ferromagnetic phase in nanoparticles. The EMR linewidth increases with the decrease of particle size. A comparison with the properties of the bulk material shows that the ferromagnetic transition at 265 K remains unaffected but the anti-ferromagnetic transition at TN = 150 K disappears in the nanoparticles. Further, the temperature dependence of magnetic anisotropy shows a complex behaviour, being higher in the nanoparticles at high temperatures, lower at lower temperatures in comparison with the bulk [20]. In Chapter 5, we present the fabrication, characterization and the results obtained from the magnetization and EMR measurements carried out on BCMO and BSMO nanoparticles and compare the results with those of the bulk. X-ray diffraction gives evidence for single phasic nature of the materials as well as their structures. Mono-dispersed to a large extent, isolated nanoparticles are seen in the transmission electron micrographs. High resolution electron microscopy shows the crystalline nature of the nanoparticles. Superconducting quantum interferometer based magnetic measurements from 10 K to 300 K show that these nanomanganites retain the charge ordering nature unlike the Pr and Nd based nanomanganites. The CO in Bi based manganites is thus found to be very robust consistent with the observation that magnetic fields of the order of 130 T are necessary to melt the CO in these compounds. These results are supported by electron magnetic resonance measurements [21]. In Chapter 6, we present our results on the effect of particle size on the magnetic properties of Pr0.7Pb0.3MnO3 (PPMO). PPMO nanoparticles of two different sizes (~5 nm and 30 nm) were prepared by the polymeric precursor sol-gel method. The samples are characterized by different techniques like XRD, TEM, SQUID magnetometry, EMR and optical spectroscopic measurements. It is found that the nanoparticles crystallize in the cubic perovskite structure. TEM measurements show that the 5 nm particles are uniform in size. They are also crystalline as seen by HREM and XRD measurements. SQUID magnetometry measurements have shown that the Curie temperature increases (from 220 K to 235 K) with the increase of particle size. Saturation magnetization is higher for the smaller particles studied. We have observed only one EMR signal down to 4 K in both the nanoparticles (5 and 30 nm) in contrast to the two EMR signal behaviour observed in bulk PPMO [22]. It is found that the EMR linewidth increases with the decrease of particle size in the paramagnetic phase. Temperature dependent optical spectroscopy measurements performed on 5 nm PPMO nanoparticles indicate that the insulator-metal transition temperature TM-I = 230 K, is not very different from TM-I = 235 K of the bulk sample [23] The thesis concludes with a brief writeup summarizing the results and pointing out possible future directions of research in the area.

Electron Magnetic Resonance

Manganites

Magnetotransport

Magnetization

Nanoscale Manganites

Colossal Magnetoresistace Nanomanganites

Electron Paramagnetic Resonance

Nanoscale Compounds - Magneto-transport

Magneto Transport

Manganite Nanotubes

Nanowires

Nanoparticles

CMR Nanomanganites

Nanomanganite

Magnetic Transport

Magnetism

Phenomenological theories of magnetic multilayers and related systems

Kyselov, Mykola

27 January 2011

In this thesis multidomain states in magnetically ordered systems with competing long-range and short range interactions are under consideration. In particular, in antiferromagnetically coupled multilayers with perpendicular anisotropy unusual multidomain textures can be stabilized due to a close competition between long-range demagnetization fields and short-range interlayer exchange coupling. These spatially inhomogeneous magnetic textures of regular multidomain configurations and irregular networks of topological defects as well as complex magnetization reversal processes are described in the frame of the phenomenological theory of magnetic domains. Using a modified model of stripe domains it is theoretically shown that the competition between dipolar coupling and antiferromagnetic interlayer exchange coupling causes an instability of ferromagnetically ordered multidomain states and results in three possible ground states: ferromagnetic multidomain state, antiferromagnetic homogeneous and antiferromagnetic multidomain states. The presented theory allows qualitatively to define the area of existence for each of these states depending on geometrical and material parameters of multilayers. In antiferromagnetically coupled superlattices with perpendicular anisotropy an applied magnetic bias field stabilizes specific multidomain states, so-called metamagnetic domains. A phenomenological theory developed in this thesis allows to derive the equilibrium sizes of metamagnetic stripe and bubble domains as functions of the antiferromagnetic exchange, the magnetic bias field, and the geometrical parameters of the multilayer. The magnetic phase diagram includes three different types of metamagnetic domain states, namely multidomains in the surface layer and in internal layers, and also mixed multidomain states may arise. Qualitative and quantitative analysis of step-like magnetization reversal shows a good agreement between the theory and experiment. Analytical equations have been derived for the stray field components of these multidomain states in perpendicular multilayer systems. In particular, closed expressions for stray fields in the case of ferromagnetic and antiferromagnetic stripes are presented. The theoretical approach provides a basis for the analysis of magnetic force microscopy (MFM) images from this class of nanomagnetic systems. Peculiarities of the MFM contrast have been calculated for realistic tip models. These characteristic features in the MFM signals can be employed for the investigations of the different multidomain modes. The methods developed for stripe-like magnetic domains are employed to calculate magnetization processes in twinned microstructures of ferromagnetic shape-memory materials. The remarkable phenomenon of giant magnetic field induced strain transformations in such ferromagnetic shape memory alloys as Ni-Mn-Ga, Ni-Mn-Al, or Fe-Pd arises as an interplay of two physical effects: (i) A martensitic transition creating competing phases, i.e. crystallographic domains or variants, which are crystallographically equivalent but have different orientation. (ii) High uniaxial magnetocrystalline anisotropy that pins the magnetization vectors along certain directions of these martensite variants. Then, an applied magnetic field can drive a microstructural transformation by which the martensitic twins, i.e. the different crystallographic domains, are redistributed in the martensitic state. Within the phenomenological (micromagnetic) theory the equilibrium parameters of multivariant stripe patterns have been derived as functions of the applied field for an extended single-crystalline plate. The calculated magnetic phase diagram allows to give a detailed description of the magnetic field-driven martensitic twin rearrangement in single crystals of magnetic shape-memory alloys. The analysis reveals the crucial role of preformed twins and of the dipolar stray-field energy for the magnetic-field driven transformation process in magnetic shape-memory materials. This work has been done in close collaboration with a group of experimentalists from Institute of Metallic Materials of IFW Dresden, Germany and San Jose Research Center of Hitachi Global Storage Technologies, United States. Comparisons between theoretical and experimental data from this cooperation are presented throughout this thesis as vital part of my work on these different subjects.

Magnetische Multischichten

Senkrechtanisotropie

Domain-Struktur

Magnetisierung

Feld-Stämme induziert

Magnetic multilayers

Perpendicular anisotropy

Antiferromagnetic interlayer exchange

Domain structure

Magnetization process

Field-induced strains

ddc:530

rvk:UP 6300

rvk:UP 6400

rvk:UP 7590

Wechselwirkungsdomänen in permanentmagnetischen Seltenerd-Übergangsmetall-Verbindungen

Thielsch, Juliane

22 April 2015

Im Rahmen der Dissertation wurde das Phänomen der Wechselwirkungsdomänen sowohl experimentell als auch unter Zuhilfenahme mikromagnetischer Simulationen untersucht. Gegenstand der Untersuchungen waren einphasige NdFeB-Magnete, die durch Heißpressen und anschließender Warmumformung hergestellt wurden. Zusätzlich wurden über den gleichen Herstellungsweg Kompositproben aus NdFeB und Fe mit unterschiedlichen Partikelausgangsgrößen erhalten und studiert. Korrelationsuntersuchungen verschiedener Messmethoden haben gezeigt, dass im thermisch entmagnetisierten Zustand die Grenzen der Wechselwirkungsdomänen an der Oberfläche größtenteils entlang von Korngrenzen verlaufen. Mittels in-situ MFM wurden erstmalig Untersuchungen von Wechselwirkungsdomänen an massiven NdFeB-Magneten im Magnetfeld durchgeführt. Die Ummagnetisierung erfolgt dabei über die Bewegung der Domänengrenze durch schrittweises Wandern von einer Korngrenze zur benachbarten. Die Beweglichkeit der Domänengrenzen ist durch das Haften an den Korngrenzen gehemmt, was sich in der geringeren Suszeptibilität der warmumgeformten Magnete im Vergleich zu Sintermagneten bemerkbar macht. Aufgrund der eingestellten Mikrostruktur in den warmumgeformten Magneten kann folglich gesagt werden, dass die Ummagnetisierungsprozesse sowohl Merkmale von klassischen Nukleations-, als auch von klassischen Pinningmagneten aufweisen. Mit Hilfe von mikromagnetischen Simulationen konnte eine Eindomänenteilchengröße prismatischer Partikel mit quadratischer Grundfläche ermittelt werden. Außerdem konnte gezeigt werden, dass der Winkel des Streufeldvektors eine entscheidende Rolle bei Ummagnetisiserungsprozessen in solchen Partikeln spielt. Die Superposition des Streufeldvektors mit dem Vektor des angelegten Feldes führt zu einem Gesamtfeldvektor, dessen Winkelabhängigkeit ein Stoner-Wohlfarth ähnliches Verhalten zeigt.

Wechselwirkungsdomänen

Magnetische Domänen

Ummagnetisiserung

Permanentmagnet

NdFeB

Magnetische Kompositproben

Warmumformung

Mikromagnetische Simulationen

in-situ MFM

Kerrmikroskopie

Interaction domains

magnetic domains

magnetization reversal

permanent magnet

NdFeB

magnetic composite samples

hot deformation

micromagnetic simulations

in-situ MFM

Kerr microscopy

ddc:620

rvk:ZM 7050

Assignment of the thalamic nuclei using structural magnetization transfer MRI and orthogonal viewers / Identifizierung von Thalamusskernen auf orthogonalen Ebenen von strukturellen Magnetisierungstransfer-MRT-Daten

Gringel, Tabea

26 September 2012

No description available.

610 Medizin, Gesundheit

MED 291 Anatomie

MED 372 Bildgebende Verfahren

Medicine

Anatomie Thalamuskerne

strukturelle Magnetisierungstransfer MRT

3 Tesla

Thalamus nuclei anatomy

structural magnetization transfer MRI

3 Tesla

44.34 Anatomie

44.64 Radiologie

Entwicklung eines quantitativen Verfahrens zur Streufeld- und Magnetisierungsbestimmung magnetischer Strukturen / Development of a quantitative method for the determination of the stray field and the magnetization of magnetic structures

Dreyer, Sebastian

03 July 2007

No description available.

530 Physik

Mathematics and Computer Science

quantitative Magnetisierung

inverses magnetostatisches Problem

hartmagnetische Strukturen

Magneto-Optische Indikatorfilm-Methode

quantitative magnetization

inverse magnetostatic problem

hardmagnetic structures

magneto-optical indicatorfilm technique

33.16

33.75

RNI 000: Magnetischer Dipol

magnetisches Dipolmoment

Magnetisierung