Estudo de materiais alternativos para aplicacao em sistemas de proteses odontologicas com conexoes magneticas / Alternative materials study for dental magnetics attachments applications

MARQUES, ROGERIO A.

09 October 2014

Made available in DSpace on 2014-10-09T12:26:12Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:10:32Z (GMT). No. of bitstreams: 0 / Materiais ferromagnéticos são investigados como possíveis candidatos para aplicações em próteses dentais em substituição aos conectores magnéticos feitos em ligas ferromagnéticas de elevado custo. Neste trabalho, três materiais foram investigados: o aço inoxidável 17-4 PH, confeccionado por moldagem de pós por injeção (PIM), a liga PM2000, obtida por mechanical alloying e endurecida por dispersão de óxidos, e o aço inoxidável 1802, isento de níquel. O ensaio de citotoxicidade in vitro mostrou que nenhum dos três materiais era citotóxico. O comportamento frente à corrosão foi estudado através de curvas de polarização anódica potenciodinâmicas e por espectroscopia de impedância eletroquímica (EIE) em solução tamponada com fosfato (PBS), a 25°C. Como material de referência, foi utilizado o aço inoxidável 316L devido ao seu amplo emprego como biomaterial, principalmente na confecção de próteses ortopédicas. Todos os materiais se mostraram passivos em condições estacionárias, mas apresentaram tendência à corrosão por pite. O que apresentou maior resistência à corrosão por pite foi o PM2000, enquanto o aço 1802 mostrou a maior susceptibilidade a este tipo de corrosão, entre os estudados. Os diagramas de Mott-Schottky indicaram que o filme passivo superficial do aço PM2000 é pelo menos uma ordem de grandeza menos dopado que o filme do aço 316L e, portanto, menos defeituoso. Os resultados apontaram para o PM2000 como um possível candidato para a substituição das ligas nobres ferromagnéticas de alto custo. / Dissertacao (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP

magnetic materials

ferromagnetism

electrochemical corrosion

biomaterials

toxicity

cytology

prostheses

dentistry

Coerência quântica macroscópica em sistemas ferromagnéticos / Macroscopic quantum coherence in ferromagnetic systems

Paula, Fagner Muruci de, 1983-

19 August 2018

Orientador: Amir Ordacgi Caldeira / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-19T09:51:01Z (GMT). No. of bitstreams: 1 Paula_FagnerMurucide_D.pdf: 4858080 bytes, checksum: a43c455fc79aac38fc3e9bd9d81abe32 (MD5) Previous issue date: 2011 / Resumo: Por muitas décadas, fenômenos quânticos foram observados com partículas microscópicas, tais como átomos, elétrons e fótons. No entanto, avanços na fabricação e controle de sistemas físicos com dimensões extremamente reduzidas vêm permitindo a manifestação de eventos quânticos em proporções gigantescas. Por exemplo, existem evidências de superposições quânticas com uma supercorrente composta por bilhões de elétrons num SQUID (Superconducting Quantum Interference Device). Motivados por tais evidências, nosso objetivo reside na busca de novos dispositivos capazes de exibir efeitos quânticos macroscópicos. Em particular, estamos interessados em sistemas ferromagnéticos que manifestem CQM (Coerência Quântica Macroscópica), isto é, ferromagnetos nos quais o campo de magnetização tunela periodicamente no tempo entre dois estados topologicamente distintos e degenerados. Nesta tese, sugerimos dois dispositivos: um ?o ferromagnético no qual uma parede de domínio tunela entre dois centros de aprisionamento arti?ciais; e um MQUID (Magnetic Quantum Interference Device), isto é, um análogo magnético do SQUID que permite efeitos de tunelamento com uma ¿supercorrente¿ formada por vórtices de spin. Esses dispositivos são úteis não só na exploração dos limites de validade da mecânica quântica, mas também abrem novas possibilidades de implementação de um bit quântico / Abstract: For many decades, quantum phenomena were observed with microscopic particles, such as atoms, electrons and photons. However, advancements in manufacture and control of physics systems with very small dimensions have allowed verifying quantum events in large proportions. For instance, there are evidences of quantum superposition with a supercurrent formed by billions of electrons on a SQUID (Superconducting Quantum Interference Device). Such evidences have driven our work in a way to investigate new devices that are capable to exhibit macroscopic quantum effects. In particular, we are interested in ferromagnetic systems that present MQC (Macroscopic Quantum Coherence), in other words, ferromagnets in which the magnetization ?eld tunnels periodically in time between two distinct and degenerate topological states. In this thesis, we have suggested two devices: a ferromagnetic wire in which a domain wall tunnels between two arti?cial pinning centers; and a MQUID (Magnetic Quantum Interference Device) that is a magnetic device analogous to SQUID that permit quantum tunneling effects with a supercurrent formed by spin vortices. These devices are useful to explore the limits of validity of quantum mechanics, as well they open new possibilities to put into operation a quantum bit / Doutorado / Física / Doutor em Ciências

Tunelamento (Física)

Macroscópico

Ferromagnetismo

Tunneling (Physics)

Macroscopic

Ferromagnetism

Novel Transport Properties Of Oxides Showing Giant Magnetoresistance

Mahendiran, R

11 1900

No description available.

Transport Phenomena

Ferromagnetic Materials

Ferromagnetism

Magnetoresistance

Manganates

Magnetism

Competição entre anisotropias perpendiculares em bicamadas de CoCrPt/Ni resolvida por ressonância ferromagnética / Perpendicular anisotropy competition in CoCrPt/Ni bilayers resolved by ferromagnetic resonance

Soares, Gabriel, 1988-

28 August 2018

Orientadora: Fanny Béron / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-28T23:44:04Z (GMT). No. of bitstreams: 1 Soares_Gabriel_M.pdf: 11563028 bytes, checksum: 679e40dbf51a0c4198966c4f0eee8e20 (MD5) Previous issue date: 2015 / Resumo: Desde a descoberta dos filmes finos magnéticos com anisotropia perpendicular, ou PMAs (Perpendicular Magentic Anisotropy, em inglês), se tornou possível aumentar drasticamente a densidade de dados em discos rígidos. Uma maneira de continuar a incrementar a densidade final de dados seria desalinhar o eixo de anisotropia uniaxial e o campo magnético de escrita. Para isso, necessita-se de materiais com anisotropia magnética intermediária, i.e, na qual o seu eixo fácil está entre a longitudinal ao plano e a sua perpendicular. A situação ótima seria com o eixo fácil a 450, teoricamente dobrando a densidade final. No entanto, fabricar grãos ou filmes com esta propriedade não é viável do ponto de vista industrial. Todavia, bicamadas podem ser utilizadas para imitar este comportamento, onde um filme com anisotropia longitudinal é depositado sobre um PMA. Além do mais, esta abordagem apresenta a possibilidade de maior velocidade de escrita. Bicamadas de CoCrPt/Ni podem ser utilizadas para este propósito, com a camada de CoCrPt como PMA e a de Ni com anisotropia longitudinal. O experimento de ressonância ferromagnética permite, a priori, resolver as contribuições de anisotropia de cada camada no sistema de bicamadas, juntamente com os mecanismos de amortecimento magnético. O objetivo principal desta dissertação de mestrado é introduzir os conceitos de experimentação e teoria desta técnica, e aplicá-los nas bicamadas de CoCrPt/Ni. Neste trabalho foram utilizados filmes já depositados por sputtering com 10 nm de Co66Cr22Pt12, seguidos de 5 a 40 nm de Ni, para investigar o efeito da camada com anisotropia longitudinal sobre o PMA. Um outro conjunto de amostras contém um espaçador de Ti entre as camadas magnéticas, a fim de se estudar a interação na interface entre elas. Os experimentos de ressonância foram realizados em varredura de frequência num analisador de rede vetorial com campos magnéticos aplicados longitudinais ou perpendiculares e numa cavidade de banda X (9,54GHZ) em função da orientação do campo aplicado. Foi verificado qualitativamente o decréscimo da energia de anisotropia longitudinal com menores espessuras de Ni nas bicamadas. No entanto, não foi possível observar a linha de absorção da camada de CoCrPt, e consequentemente, encontrar unequivocamente as constantes de anisotropia do sistema, muito menos confirmar o comportamento multiaxial encontrado. Não obstante, foi confirmado a natureza de curto alcance da interação entre as camadas. Nova experimentação em outras bandas de frequência é necessária, afim de identificar a absorção do CoCrPt. Uma perspectiva futura interessante é o estudo da largura de linha e o amortecimento magnético do sistema devido a interação envolvida / Abstract: Since the advent of perpendicular magnetic anisotropy media, or PMAs, it was possible to greatly enhance the data density of hard drives. A method to push forward the data density increase is to misalign the anisotropy and applied field axes. This can be achieved by tilted media, i.e., in which the anisotropy axis lays somewhere between in-plane (IP) and out-of-plane (OOP). The optimal condition is with the axis tilted by 45\textsuperscript{0}. However, produce this kind of material is not practible at industrial scale. Thus, composite media can be used to mimic this behavior, where an in-plane anisotropy media is deposited on top of a PMA. Nonetheless, this approach allows to reach faster switching rates. CoCrPt/Ni bilayers may be used for this purpose, with the CoCrPt serving as the PMA and the Ni as the IP anisotropy layer. The ferromagnetic resonance experiment (FMR) can be used to obtain information about the magnetic anisotropy, being able to characterize its constant for each layer in the bilayer system, together with the damping mechanisms. Therefore, the main goal of this master thesis is to introduce the FMR theory and experimentation and apply them in this system. The used films were already deposited by sputtering with 10 nm of Co.66Cr.24Pt.12 under a 5 to 40 nm Ni layer. Another set of samples with a Ti layer between the magnetic layers provides information of the interface coupling. The FMR experiments were partly performed in a broadband vector network analyzer (VNA) with applied magnetic fields IP or OOP, and in a X-band (9,54 GHz) cavity as function of the orientation of the applied magnetic field. It was qualitatively verified a decrease of the longitudinal magnetic anisotropy energy as a function of the Ni thickness in the bilayer system. However, the CoCrPt single layer absorption could not be observed, making it impossible to unequivocally identify each anistropy constant. Nonetheless, the short-range nature of the coupling was confirmed. Further experimentation in higher frequencies is needed in order to find the CoCrPt absorption. Also, promising effects in the damping mechanism due to the coupling are expected / Mestrado / Física / Mestre em Física / 2013/1186360 / CAPES

Ferromagnetismo

Ressonância ferromagnética

Filmes finos

Ferromagnetism

Ferromagnetic resonance

Thin films

Supravodivost a magnetické vlastnosti slitin y-U a jejich hydridů / Superconductivity and electronic properties of y-U alloys and their hydrides

Tkach, Ilya

January 2015

Title: Superconductivity and electronic properties of γ-U alloys and their hydrides. Author: Ilya Tkach Department / Institute: Department of Condensed Matter Physics, Faculty of Mathematics and Physics, Charles University Supervisor of the doctoral thesis: Doc. RNDr. Ladislav Havela, CSc., Department of Condensed Matter Physics, Faculty of Mathematics and Physics, Charles University, Prague, The Czech Republic Abstract: Low-temperature electronic properties for U-Mo and U-Zr splats stabilized in γ-U were investigated. Magnetic measurements revealed Pauli paramagnetic behavior with temperature independent susceptibility for U-Mo alloys. U-Mo and U- Zr splats become superconducting at low temperatures with Tc up to 2.1 K and critical field 5-6 T. The superconductivity of -U can be considered as a bulk effect and can be described by the BCS theory, while -U superconductivity is not a real bulk effect. U-Mo and U-Zr alloys absorb hydrogen at high pressures (p ≥ 4.5 bar) and form hydrides with stoichiometry analogous to UH3. The hydrides with Mo have an amorphous structure based on β-UH3 phase, while hydrides with Zr have a crystalline structure of the -UH3 type. (UH3)1-xMox hydrides are ferromagnetic with enhanced TC up to 202 K and magnetic moments 1.1 μB/U in comparison with pure β-UH3 (175 K; 0.87 μB/U)....

Variation of the electronic states of Ca2RuO4 and Sr2RuO4 under uniaxial pressures / 一軸性圧力によって実現するCa2RuO4およびSr2RuO4の多彩な電子状態

Taniguchi, Haruka

23 May 2014

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18445号 / 理博第4005号 / 新制||理||1577(附属図書館) / 31323 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 前野 悦輝, 教授 石田 憲二, 教授 田中 耕一郎 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

uniaxial pressure

ruthenium oxide

superconductivity

Mott transition

itinerant ferromagnetism

400

Ferromagnetic critical behavior and critical universality in itinerant-electron metamagnet UCoAl / 遍歴電子系メタ磁性体UCoAlにおける強磁性臨界現象と臨界普遍性

Karube, Kosuke

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18777号 / 理博第4035号 / 新制||理||1581(附属図書館) / 31728 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 石田 憲二, 教授 田中 耕一郎, 教授 前野 悦輝 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

UCoAl

Metamagnetism

Ferromagnetism

Critical phenomena

Nuclear Magnetic Resonance

400

Optical control and probe of ferromagnetic and ferroic orders in films, heterostructures, and perovskite-based material systems

Smith, Nicholas William

04 December 2023

This dissertation is focused on ferromagnetic, multiferroics, and two-dimensional (2D) perovskites, exploring different unique collective magnetic and ferroic characters: (1) ferromagnetic thin film Co/Pd multilayers, (2) BaTiO3-BiFeO3 (BTO-BFO) a magneto-electric materials system, and (3) CuCl4 halide organic-inorganic perovskites. Low-power all-optical memory offers a unique opportunity to achieve ultra-fast magnetic switching in which the switching dynamics are not thermally mediated and occur on the order of the laser pulse. However, it is challenging to achieve a low-power optically excited magnetization precession angle above 90 degrees, which is required for magnetic switching. Co/Pd thin film multilayers were investigated for their potentially large perpendicular magnetic anisotropy (PMA) with three differing regimes of magnetic anisotropy: in-plane, weakly out-of-plane, and out-of-plane. Utilizing the time-resolved magneto-optical Kerr effect (TR-MOKE), we observed clear magnetic precession (on the order of a few GHz) with magnetic precession angle increasing (up to 4.5 degrees) for thinner Co samples which demonstrated stronger PMA. We observed a clear connection between PMA strength and precession amplitude as well as a large efficiency of energy transfer between spin and orbital subsystems for our strongest PMA sample. BTO-BFO is a strong room-temperature multiferroic with enhanced magneto-electric properties compared to BFO. We utilized time-resolved differential reflectivity (TR-DR) and TR-MOKE to observe strong coherent acoustic phonons in thin films as well as nanorods. Our nanorods showed additional modes (a new 20 GHz and 6 GHz mode) not observed in thin films including the fast 33 GHz mode which showed some weak tunability with high magnetic fields (up to 10 T). The observed tunability of these modes in an external magnetic field shows interesting coupling between magnetic moment and phononic modes which may be caused by the breaking of the spin-cycloid at the interface of the nanorods and the surface of the nanorods. We also observed second harmonic generation (SHG) emission which demonstrated a large enhancement in our nanorod structures with further observation of wavelength dependence. Finally, ferromagnetic resonance on our nanorod and thin film BTO-BFO structures indicated very weak Gilbert damping (on the order of 10−3), demonstrating the practicality of our structure for low-spin loss applications. Lastly, this dissertation focuses on a project around CuCl4 and CuCl2Br2 perovskites in which we observed time-dependent SHG. An increase in SHG as a function of infrared laser exposure is shown to coincide with changes in the crystal structure of the Cu perovskite materials. This increase in SHG was shown to last for a few days after hours of laser exposure indicating a slow hysteretic change to the crystal structure of the perovskites. / Doctor of Philosophy / Multifunctionality in materials is important for various applications including future mem- ory devices where ferromagnetism (collective magnetic order), ferroelectricity (collective electric polarization order), and piezoelectricity (collective strain order) can be implemented in a given device. This dissertation centers on three material systems for exploring ferroic orders: Co/Pd thin multilayers, BaTiO3-BiFeO3 (BTO-BFO) films and nano-rod arrays, and Cu halide organic-inorganic perovskite thin films and 2D structures. Co/Pd thin films demonstrate interesting ferromagnetic order with magnetic anisotropy in which the magnetization of the thin film has a preferred direction based on the thickness of the thin film. BTO-BFO demonstrates coupling between ferroelectric and antiferromagnetic order. The magnetic information may be controlled by applying electric fields or strain and Cu halide perovskites demonstrate potentially created ferroelectric order under long-term laser expo- sure with high ferroelectric switching speeds. Dynamics and nonlinear optical responses in these materials systems were explored with Ti:Sapphire pulsed lasers (∼ 100 fs). Our techniques allowed us for a better understanding of fast carrier and spin dynamics after optical excitation. Furthermore, nonlinear optics, in which two or more photons can be used to emit higher energy photons, were employed to explore the ferroelectric properties within these material systems. The results presented in this dissertation provided information on collective orders and fundamental interactions in several less-explored material systems.

Ultrafast

Optics

Magnetization Dynamics

Ferromagnetism

Ferroelectricity

Multiferroics

Perovskites

MAGNETISM IN A NUMBER OF METAL ORGANIC FRAMEWORKS (MOFs) WITH 1D AND 3D CHARACTERISTICS: AN EXPERIMENTAL AND ANALYTICAL STUDY

Hamida, Youcef

January 2012

Metal Organic Frameworks (MOFs) exhibit many excellent physical properties including magnetic properties for potential applications in devices. More importantly for the subject of this thesis, MOFs are ideal for the realization of low dimensional magnetism because of the large selection of ligands connecting magnetic centers in making the framework. The materials studied in this thesis include ten magnetic MOFs of the form M(L1)(L2) [M = Cu, Ni, Co, Fe, Mn; L1 = NDC, bpdc, BDC, BODC, N3; L2 = DMF, H2O, TED, bpy]. Polycrystalline powder samples as well as single crystal samples were synthesized. Their crystal structures were determined, and their magnetic and thermodynamic properties were measured and analyzed. Eight of these materials were characterized as 1D magnets and two as 3D magnets. In the 1D case it is found that above Tm [the temperature at which the magnetic susceptibility χ(T) has a peak] the magnetic behavior of MOFs (S ≥ 1) can be well described with the Classical Fisher Model (CFM). Near and below TC the spins take a more definite orientation than allowed for in the CFM and hence the Ising Model (IM) was used for fitting. Both CFM and IM yield fairly consistent intrachain couplings (J) when applied in their appropriate temperature region. To estimate the interchain exchange (J′), the susceptibility for a magnetic chain in the mean field of neighboring chains is used. In all cases, as expected, the ratio of J to J′ was less than 10%. The special case of Cu(N3)2bpy (S = ½) was analyzed with the spin ½ IM. Although the specific heat data (Ctotal) for most of the 1D MOFs showed no clear phase transition, a low temperature fit to the electron-phonon specific heats yielded apparent heavy fermion-like &gamma values on the order of several hundred mJ/mol K2. The lattice specific heat (C lattice) was estimated using a Debye-Einstein hybrid model. Subtracting Clattice from Ctotal, magnetic specific heat (CM) with a broad peak characteristic of low dimensional magnetism was obtained. The peak in CM was at temperature near that expected from χ(T) fits. The J values obtained from the magnetic specific heat fits were in good agreement with those obtained from χ(T) fits. Once the magnetic specific heat was accounted for, γtakes values in the expected range of few mJ/mol K2. For 3D MOFs [Mn(N3)2bpy and Fe(N3)2bpy], the existence of long range canted antiferromagnetic ordering was observed in both magnetic and specific heat measurements with phase transitions at 38 K and 20 K in the case of Mn(N3)2bpy and Fe(N3)2bpy, respectively. These transition temperatures are considered fairly high for molecular based materials. In both Mn(N3)2bpy and Fe(N3)2bpy, the χ(T) data fit well to the Heisenberg model for a diamond-type network. The transition can clearly be seen with an abrupt increase in the magnetization below TC and a shift to a higher temperature in the specific heat when measured under an applied magnetic field. The systematic approach in this work led to the successful estimate of C lattice resulting in meaningful fitting of χ(T) and Cmagnetic to the appropriate theoretical models in magnetism. It also led the discovery of ferrimagnets or canted antiferromagnets M(N3)2bpy with large coercivity and rather high transition temperature. The results of this study have been published in three articles in the Journal of Applied physics, and two manuscripts are under preparation for submission [1-5]. / Physics

Physics

Physics, Condensed Matter

Canted

Ferromagnetism

Heisenberg

Ising

Magnetism

Mof

Magnetic couplings and superparamagnetic properties of spinel ferrite nanoparticles

Vestal, Christy Riann

03 1900

No description available.

Ferromagnetism

Ferrites (Magnetic materials)

Nanoparticles Magnetic properties

Spinel Magnetic properties

Ferrites (Magnetic materials)

Ferromagnetism

Nanoparticles Magnetic properties

Spinel Magnetic properties