Sistemas porosos de zircônia e céria / Zirconia-Ceria Porous Systems

Rebeca Bacani

16 December 2009

Neste trabalho foram desenvolvidas sínteses de ZrO2-x%CeO2, baseadas na preparação da sílica mesoporosa ordenada SBA-15, utilizando um molde de co-polímero tribloco Pluronic P-123, diversos precursores de zircônio e cério e diferentes métodos. Os métodos de síntese testados foram com: precursores a base de cloreto hidratado (com x=50, 70 e 90), precursores a base de cloreto anidro (x=50 e 90), precursores a base de nitrato (x=90), solução supersaturada de nitrato (x=90), do tipo híbrido com Zr, Ce e Si (com 10%mol de Si e x=90), paliçada de Si (com 10 e 30%mol de Si e x=90) e paliçada de Si com temperatura de síntese de 40°C (com 30%mol de Si e x=90). Visando obter paredes compostas por fase cristalina única e grande área supercial, para futuras aplicações em catálise. Os compósitos polímero/(zircônio-cério) sintetizados a partir de cloretos formam uma estrutura lamelar organizada, que se transforma num sistema poroso desordenado após a calcinação para a retirada do molde. O processo de decomposição/remoção do molde até 540°C produz mudanças de fase nos precursores a base dos metais utilizados, além das transformações morfológicas. Para uma concentração de 90% de CeO2 obtém-se um material poroso com paredes homogêneas de estrutura fcc e de maior estabilidade mecânica. Os valores de área supercial e volume de poros dependem fundamentalmente do método de preparação do material e independem da concentração de CeO2. Aumentos signicativos da área supercial (~100m²/g) e do volume de poros (~0,4cm³/g) são obtidos a partir da introdução de sílica nesses sistemas. Foram alcançados área supercial aproximadamente 6 vezes maior e tamanho de cristalito ~4 vezes superior à do material similar nanocristalino preparado por gel-combustão. Esses valores também são iguais aos reportados para os melhores materiais porosos a base de zircônia-céria, preparados por outros métodos, encontrados na literatura. / In this work synthesis of ZrO2-x%CeO2 were developed, based on the formation of ordered mesoporous silica SBA-15, using the triblock co-polymer Pluronic P-123 as template, different precursors of zirconium and cerium and dierent methods. The tested synthesis methods were with: hydrated chloride precursors (with x=50, 70 and 90), anhydrous chloride precursors (x=50 and 90), nitrate precursors (x=90), supersaturated nitrate solution (x=90), hybrid type with Zr, Ce and Si (with 10%mol of Si and x=90), Si palisade (with 10 and 30%mol of Si, and x=90) and Si palisade with synthesis temperature of 40°C (with 30%mol of Si and x=90). Aiming to obtain crystalline single phase walls and large supercial area, for future applications in catalysis. The composites polymer/zirconium-cerium synthesized from chloride precursors formed an organized lamellar structure, which transforms into a disordered porous system after the calcination to remove the template. The template decomposition/removal up to 540°C produces phase transformations in the metallic precursors, besides morphological changes. A CeO2 content of 90% resulted in a porous material with homogeneous walls of fcc structure and better mechanical stability. The values of supercial area and pore volume depend mostly on the preparation method rather than the CeO2 concentration. Signicant increases on supercial area (~100m²/g) and pore volume (~0.4cm³/g) were obtained with the introduction of silica into the material. Supercial area ~6 times larger and crystallite size ~4 times superior to a nanocrystalline similar material, made by gel-combustion were attained. These figures are also equal to the ones reported for the best porous zirconia-ceria materials, prepared by other routes, found in the literature.

céria

Física da matéria condensada

mesoporoso

SAXS

zircônia

ceria

Condensed matter physics

mesoporous

SAXS

zirconia

Dissociação da molécula de água em superfícies de silício: um estudo teórico / Dissociation of water molecule on silicon surfects: a theoretical study

Regina Lélis de Sousa

03 March 2010

O silício é o material-base para a indústria de microeletrônica e tem acompanhado a evolução para a nanoeletrônica. Em várias aplicações é importante o processo de química molhada que prevê a presença de moléculas de água na superfície do semicondutor. Todavia, muito pouco ainda é conhecido, teórica e experimentalmente, sobre os mecanismos e as estruturas resultantes da reação da molécula de H2O sobre Si. Aqui, nós apresentamos nosso estudo da dissociação de uma molécula de água sobre as superfícies Si(100)(2x1) (superfície limpa) e Si(100)(2x1):H superfcie monohidrogenada). Nossos resultados foram obtidos com a Teoria do Funcional da Densidade (DFT), enquanto os caminhos de menor energia para a decomposição da molécula sobre a superfície foram obtidos com a metodologia denominada CI-NEB (Climbing Image - Nudging Elastic Band). Nossos resultados mostraram que a dissociação da molécula de água sobre a superfície limpa é independente do sítio de ataque à superf´cie e esta interação ocorre de maneira correlacionada. O produto HSiSiOH desta reação é estável, e a posterior decomposição ocorre via energia térmica. Neste caso, nós mostramos que a transferência do átomo de oxigênio para o dímero é energética e cineticamente favorável em relação à oxidação de sítios subsuperficiais. A superfície monohidrogenda mostra-se muito resistente ao ataque oxidativo. Constatamos que alguns processos oxidativos tem dependêencia com o sítio de ataque, enquanto outros são indiferentes se a interação ocorre em regiões de vale ou sobre a fileira de dímeros. Nossos resultados evidenciam que a rota de ataque sugerida pelos experimentais nao se mostrou cineticamente viável. Assim, nós propomos duas novas rotas oxidativas, uma relacionada à oxidação do dímero e outra de sítio de subsuperfície. Nós provamos que estas duas novas possibilidades são cinética e energéticamente viáveis. Finalmente, apresentamos uma análise das modificações do perfil de corrente de tunelamento (STM - Scanning Tunneling Microscopy) provocadas por estes defeitos. Deste modo, n´os esperamos que este trabalho possa ser uma motivação para a comprovação de nossos resultados. / Silicon is the basic material for microeletronics industry, and for the recent developments in nano eletronics. In many applications, wet chemistry processing is important that is, with the presence of water molecules on the semiconductor surface. However, the reaction mechanism for the H2O molecule with Si, and the resulting structures, are still object of debate, from both theoretical and experimental points of view. Here, we present a detailed study of the dissociation of one water molecule on the surfaces Si (100) (2x1) (clean surface) and Si (100) (2x1): H ) monohydride, covering from the reaction evolution, to the characterization of the final surface. To do that, we use methodologies based on Density Functional Theory the reaction pathways for decomposition of the water molecule on the surface have been carried out with CI-NEB (climbing image nudging elastic band), and we used the Tersoff-Hamann model for surface characterization. Our results show that the water molecule dissociation on the clean surface is independent of the site of attack. The product of this reaction, H-Si-Si-OH unit, is stable and its subsequent decomposition occurs through thermal energy. We also find that the insertion of the oxygen atom a Si surface dimmer is energetically and kinetically favorable compared to absorption in the back-bond (subsurface) sites. Although hydrogenation cannot prevent oxidation of the surface, we can say that the passivation processes are efficient, since the monohydride surface is more resistant to attack by oxygen. In contrast with the clean surface, for this case, some oxidative process have dependency on the site of attack, while others are indifferent whether the interaction occurs in the valley or over the dimmer rows. Our results indicate that the oxidation route suggested by earlier experimental works is not favored. In this way, we propose two new oxidation routes, once related to chemisorption of the oxygen atom on the Si-Si dimmer bond, and another related to the absorption on the back bond, with simultaneous ejection of one H2 molecule. Analysis of energy barriers showed that these two new possibilities are both kinetically and energetically viable. We finally present analyses of the profiles of tunneling current, predicted by STM (Scanning Tunneling Microscopy) for oxygen incorporation in all studied structures. We hope to have contribuited to the understanding of the oxidation processes, and at the same time to motivate new experimental investigations

Fisica da Matéria Condensada

Física do Estado Sólido

Condensed Matter Physics

Porperties of Solids

Solid State Physics

Fabricação e caracterização de filmes semicondutores de InN depositados com o método de deposição assistida por feixe de íons / Growth and caracterization of ImN semiconductor films by ion beam assisted deposition

Karina Carvalho Lopes

31 October 2008

Neste trabalho, analisamos as propriedades estruturais, morfológicas e óticas de filmes finos de nitreto de índio, depositados em diferentes tipos de substratos (Si , safira-C, safira-A, safira-R, GaN/ safira e vidro) pelo método de deposição as s i s t ida por feixe de elétrons com energia de íons entre 100 e 1180 eV. A temperatura de substrato durante o processo de deposição variou da temperatura ambiente (TA) à 450oC, e ARR( I/A) ,que é a razão do f luxo de íons incidentes no feixe de íons relativa ao f luxo de átomos de In evaporados , de 0,8 até 4,5. O crescimento de InN cristalino foi fortemente influenciado pela orientação cristalográfica do substrato e os filmes sobre safira-C, safira-A e GaN/ safira foram os que apresentaram maior cristalinidade. O melhor valor de energia de íons foi de 100 eV para a formação de InN cristalino e sua cristalinidade aumentou com o aumento da temperatura do substrato. Não observamos influências de ARR( I/A) sobre a cristalinidade de InN e os filmes preparados em TA sobre GaN/ safira apresentaram InN amorfo. / In thi s work, we analyzed the structural , morphological and optical properties of thin indium nitride films grown on some types of subs t rate (Si , c-plane sapphire, a-plane sapphire, r -plane sapphire, GaN/ sapphire and glass ) by the ion beam as s is ted deposition method with ion energy of 100-1180 eV. The substrate temperature during deposition ranged from room temperature (RT) to 450oC and ARR ( I/A) , from 0.8 to 4.5. The growth of crystalline InN was strongly influenced by the crystallographic orientation of substrate and the films on c-plane sapphire, a-plane sapphire and GaN/ sapphire provided more favorable result s . The best value of ion energy was found to be 100 eV for the format ion of crystalline InN and this crystallization increased with increasing the substrate temperature. We found that influence of ARR( I/A) on the crystallization of InN was imperceptible and that the f ilm prepared at RT on the GaN/ sapphire was amorphous of InN.

Filmes finos

Física da matéria condensada

Nitreto de Indio

Semicondutores

Condensed matter physics

Indium nitride

Semiconductors

Thin films

Novos funcionais para o modelo de Heisenberg anisotrópico / New functionals for the anisotropic Heisenberg model

Guilherme Nery Prata

30 May 2008

O modelo de Heisenberg destaca-se no estudo do magnetismo com origem em momentos magnéticos localizados. Semelhante ao bem conhecido modelo clássico de Ising, ele incorpora, no entanto, flutuações quânticas. Estamos interessados em sistemas antiferromagnéticos descritos pelo Hamiltoniano de Heisenberg com anisotropia de troca e que, eventualmente, possam apresentar magnetizações não-nulas. Neste trabalho, lidamos com sistemas não-homogêneos, apresentando impurezas e/ou sujeitos a condições de contorno abertas. Para tanto, utilizamos a Teoria do Funcional da Densidade, que proporciona uma metodologia de obtenção de resultados para um sistema não-homogêneo a partir dos resultados conhecidos do mesmo sistema quando homogêneo. Nosso trabalho resume-se a duas partes. Na primeira parte, trabalhamos inicialmente com um funcional, na aproximação ``local para o spin\'\'(LSA), advindo da Teoria de Ondas de Spin, válido para anisotropia de troca com simetria XXZ e magnetização do sistema nula. E na segunda, exploramos a possibilidade de construção de um funcional, na aproximação LSA, válido para anisotropia de troca mas com um adicional: válido para magnetizações não-nulas. Os resultados advindos dos funcionais são confrontados com resultados numericamente exatos obtidos de um programa em Fortran 90, que diagonaliza cadeias de spins na presença ou não de impurezas, para qualquer condição de contorno, descritas pelo modelo de Heisenberg com anisotropia de troca. / The Heisenberg Model is generally recognized in the study of electromagnetism with origin in localized magnetic moments. Similar to the well known classical Ising model, it incorporates, however, quantum flutuations. We are interested in antiferromagnetic systems described by the Heisenberg Hamiltonian with exchange anisotropy and, eventually, non-null magnetizations. In this work, we deal with non-homogeneous systems with impurities. For this, we use Density Functional Theory and the Local Spin Aproximation (LSA), which provide a methodology for obtaining results of a non-homogeneous system from known results of the same but homogeneous system. Initially, we work with a functional provided by Spin Wave Theory on the LSA approximation, valid for anisotropies with XXZ simmetry and null magnetization. After that, we deal with the possibility of building a functional on LSA approximation valid also for exchange anisotropy but with an additional: applicable for non-null magnetizations.

Física de matéria condensada

Modelo de Heisenberg

Teoria do funcional da densidade

Condensed matter physics

Density-functional theory

Heisenberg model

Sistemas carregados: modelos de simulação / Charged sistems : models of simulation

Wagner Gomes Rodrigues Junior

13 December 2011

Neste trabalho apresentamos uma revisão de métodos de simulação de energia eletrostática de sistemas de cargas e uma proposta de adaptação de algoritmo ultilizado na literatura de sistemas gravitacionais para estudo das propriedades estatísticas de sistemas coulombianos. Na primeira parte do estudo, revisamos os fundamentos teóricos do método de Ewald e suas condições de aplicabilidade, procurando esclarecer as referências mais importantes no assunto, que são de difícil compreensão, gerando equívocos na utilização do termo de dipolo. Detalhamos o estudo sobre a análise da convergência da série em que a técnica se baseia, bem como sua interpretação física mostrando a equivalência entre as duas abordagens . Na segunda parte do trabalho analisamos os fundamentos do Fast Multipole Method desenvolvido para interação gravitacional, para o qual construímos programas em linguagem C para uma versão na rede. Criamos um algoritmo que denominamos Fast Multipole Monte Carlo (FMMC) e desenvolvemos um programa para cálculo das propriedades termodinâmicas de sistemas coulombianos. Os programas são testados comparando resultados para a energia e propriedades térmicas do modelo LRPM com resultados de simulação através de cálculo direto. / In this work we present a review of methods of simulation for the electrostatic energy of charged systems and an adaptation of an algorithm from the literature on gravitational systems for the study of the statistical properties of Coulomb systems. In the first part of the work, we review the fundamentals for the theoretical method of Ewald and its conditions of applicability, seeking to clarify the most important references on the subject, which because of the involved mathematics, have led to misuse of the so-called dipole correction. We detail the study on the convergence of the series for the electrostatic potential on which the Ewald technique is based, as well as the physical interpretation given elsewhere, showing the equivalence between the two approaches. In the second part of this work, we analyse the foundations of the Fast Multipole Method developed for gravitational interactions, and present programs in C language for a network version of neutral charged systems. Finally, an algorithm, which we name Fast Multipole Monte Carlo, and the corresponding code for calculating the thermodynamic properties of Coulomb systems are presented. The programs are tested by comparing results for the energy and thermal properties of the Lattice Restricted Primitive model with results of simulations based on direct calculations for the Coulomb energies.

Cristais Líquidos

Física da Matéria Condensada

Física do Estado Líquido

Condensed matter physics

liquid crystals

physics of liquid state

Modelagem ab initio da interação proteína-carboidrato / Ab initio modeling of protein - carbohydrate interaction

Filipe Camargo Dalmatti Alves Lima

20 August 2010

A Frutalina é uma proteína tetramérica ligante de carboidratos obtida através de sementes Artocarpus incisa. Os interesses biomédicos da Frutalina estão em sua alta afnidade de ligação por carboidratos presentes em algumas células tumorais específicas. Até agora, nenhum estudo teórico computacional foi realizado para investigar as características de ligação da Frutalina. Neste trabalho, através de um estudo multidisciplinar, investigamos as propriedades de ligação e óticas da Frutalina com carboidratos. Utilizamos um modelo-corte teórico, considerando apenas o sítio ativo de ligação com o carboidrato construído com o auxílio de docking molecular e mecânica molecular clássica. As energias de ligação são obtidas através de uma abordagem quântica ab initio all electron, dentro da Teoria do Funcional da Densidade (DFT), no espaço recíproco que combina o método Projector Augmented Waves (PAW) e a dinâmica molecular de Car-Parrinello (CP). Uma metodologia Hartree-Fock (HF) semi-empírica é utilizada para obter as propriedades óticas. A investigação deste problema muito complexo pode ser dividido em seis etapas principais: a) estudamos as propriedades estruturais da proteína para avaliar a sua mobilidade e escolhemos um conjunto de dados de raios-X para descrever o sistema; b) aplicamos a técnica de docking molecular para ligar quatro carboidratos ( alfa-metil-D-galactose, beta-D-galactose, O1-metil-manose e alfa-metil-D-glucopiranose) na proteína; c) otimizamos a geometria do sistema lectina-carboidrato utilizando mecânica molecular clássica; d) criamos o modelo-corte ; e) investigamos as propriedades óticas utilizando HF; f) estudamos as propriedades eletrônicas do sistema proteína-carboidrato e calculamos energias de ligação através do cálculo DFT. O modelo aqui proposto, além de apresentar uma adequada concordância com dados experimentais, abre a possibilidade de investigar propriedades eletrônicas através de uma abordagem quântica estado da arte na área de estrutura eletrônica. / Frutalin is a tetrameric carbohydrate-binding protein obtained from breadfruit seeds. Biomedical interest on Frutalin comes from the high afinity exhibited by these molecules toward carbohydrates expressed by specific tumor cells. So far, no theoretical computational studies have been carried out to investigate the binding characteristics of frutalin, which is probably due to the large number of atoms that should be considered for in silicon calculations. We investigate the binding of frutalin and optical properties with specific carbohydrate molecules using a theoretical cutmodel considering only the carbohydrate binding site. This model has been constructed with the aid of molecular docking and classical molecular mechanics. We use the ab initio all electron reciprocal space Projector Augmented Waves (PAW) method and the Car-Parrinello scheme as embodied in the CP-PAW code to obtain the binding energies. To evaluate the optical properties, we employed the Hartree-Fock Semi-empirical ZINDO method from the Materials Studio 4.0 computational package. The investigation of this very complex problem can be divided into 6 main steps. Firstly, we study the structural properties of the protein to evaluate its mobility and we choose a x-ray data to describe reliably the system. In the second step, we performed molecular docking to link up four carbohydrates (alpha-methyl-D-galactoside, beta-D-galactoside, O1-methyl-mannose and methyl-alpha-D-glucopyranoside) in the protein. We optimize the geometry of the system lectin-carbohydrate using molecular mechanics in the third step. In the fourth step, we created the cutmodel based on the final geometries obtained in the previous step. In the fifth and sixth steps we investigate the quantum interaction of the protein with each carbohydrate. Our theoretical results are compared with available measurements in each step. The study of the interaction between the active binding site and carbohydrates allows us to demonstrate that our methodology is well suited to predict the electronic properties of the system.

Biofísica

Física

Física computacional

Física da matéria condensada

Biophysics

Computational physics

Condensed matter physics

Physics

Low Dimensionality Effects in Complex Magnetic Oxides

Lampen Kelley, Paula J.

01 January 2015

Complex magnetic oxides represent a unique intersection of immense technological importance and fascinating physical phenomena originating from interwoven structural, electronic and magnetic degrees of freedom. The resulting energetically close competing orders can be controllably selected through external fields. Competing interactions and disorder represent an additional opportunity to systematically manipulate the properties of pure magnetic systems, leading to frustration, glassiness, and other novel phenomena while finite sample dimension plays a similar role in systems with long-range cooperative effects or large correlation lengths. A rigorous understanding of these effects in strongly correlated oxides is key to manipulating their functionality and device performance, but remains a challenging task. In this dissertation, we examine a number of problems related to intrinsic and extrinsic low dimensionality, disorder, and competing interactions in magnetic oxides by applying a unique combination of standard magnetometry techniques and unconventional magnetocaloric effect and transverse susceptibility measurements. The influence of dimensionality and disorder on the nature and critical properties of phase transitions in manganites is illustrated in La0.7Ca0.3MnO3, in which both size reduction to the nanoscale and chemically-controlled quenched disorder are observed to induce a progressive weakening of the first-order nature of the transition, despite acting through the distinct mechanisms of surface effects and site dilution. In the second-order material La0.8Ca0.2MnO3, a strong magnetic field is found to drive the system toward its tricritical point as competition between exchange interactions in the inhomogeneous ground state is suppressed. In the presence of large phase separation stabilized by chemical disorder and long-range strain, dimensionality has a profound effect. With the systematic reduction of particle size in microscale-phase-separated (La, Pr, Ca)MnO3 we observe a disruption of the long-range glassy strains associated with the charge-ordered phase in the bulk, lowering the field and pressure threshold for charge-order melting and increasing the ferromagnetic volume fraction as particle size is decreased. The long-range charge-ordered phase becomes completely suppressed when the particle size falls below 100 nm. In contrast, low dimensionality in the geometrically frustrated pseudo-1D spin chain compound Ca3Co2O6 is intrinsic, arising from the crystal lattice. We establish a comprehensive phase diagram for this exotic system consistent with recent reports of an incommensurate ground state and identify new sub-features of the ferrimagnetic phase. When defects in the form of grain boundaries are incorporated into the system the low-temperature slow-dynamic state is weakened, and new crossover phenomena emerge in the spin relaxation behavior along with an increased distribution of relaxation times. The presence of both disorder and randomness leads to a spin-glass-like state, as observed in γFe2O3 hollow nanoparticles, where freezing of surface spins at low temperature generates an irreversible magnetization component and an associated exchange-biasing effect. Our results point to distinct dynamic behaviors on the inner and outer surfaces of the hollow structures. Overall, these studies yield new physical insights into the role of dimensionality and disorder in these complex oxide systems and highlight the sensitivity of their manifested magnetic ground states to extrinsic factors, leading in many cases to crossover behaviors where the balance between competing phases is altered, or to the emergence of entirely new magnetic phenomena.

Manganites

Nanostructures

Frustrated Magnetism

Phase Coexistence

Magnetocaloric Effect

Critical Exponents

Condensed Matter Physics

Tailoring the Magnetic Properties of Amorphous TbCo Nano Films

Djurberg, Viktor

January 2018

The possibility to change magnetic anisotropy of amorphous TbCo films from out-of-plane to in-plane has been investigated. The effects of TbCo film's thickness and composition on the magnetic anisotropy were investigated together with the effects of growing the TbCo films on a SmCo seed layer. This was studied by sputtering TbCo films of composition Tb_xCo_(100-x) x=16,18,20,22 and 24, with thickness ranging between 2-20 nm, with and without the presence of a 20 nmSm_15Co_85 seed layer. All films were grown in a 130 mT magnetic in-plain field to imprint an in-plane anisotropy. The structure and composition of the films were examined with Rutherford backscattering spectrometry, X-ray reflectivity, and Grazing incidence X-ray diffraction. The magnetic properties of the films were studied with magneto-optic Kerr effect measurement, vibrating sample magnetometer, Kerr microscopy and magnetic force microscopy. The magneto-optic Kerr effect measurement showed that it was possible to change TbCo film's preferred magnetization direction from out-of-plane to in-plane by reducing the film thickness. The SmCo layer made it easier for theTbCo films to change preferred magnetization direction from out-of-plane to in-plane.

Magnetic properties

Amorphous TbCo film

Magnetic Anisotropy

Interface effects

Condensed Matter Physics

Den kondenserade materiens fysik

Approximation of ab initio potentials of carbon nanomaterials with machine learning

Lundberg, Oscar, Bjersing, Oskar, Eriksson, Martin

January 2017

In this work potentials of carbon nanomaterials calculated with Density Functional Theory (DFT) are approximated using an Artificial Neural Network (ANN). Previous work in this field has focused on estimating potential energies of bulk structures. We investigate the possibility to approximate both the potential energies and the forces of periodic carbon nanotubes (CNTs) and fullerenes. The results indicate that for test structures similar to those in the training set the ANN approximates the energies to within 270 meV/atom (&lt; 3.7% error, RMSE 40 meV/atom) and the forces to within 7.5 eV/Å (&lt; 73% error, RMSE 1.34 eV/Å) per atom compared with DFT calculations. Furthermore, we investigate how well the ANN approximates the potentials and forces in structures that are combinations of CNTs and fullerenes (capped CNTs) and find that the ANN generalizes the potential energies to within 100 meV/atom (&lt; 1.1% error, RMSE 78 meV/atom) and the forces to within 6 eV/Å (&lt; 60% error, RMSE 0.55 eV/Å) per atom. The ANN approximated potentials and forces are used to geometry optimize CNTs and we observe that the optimized periodic CNTs match DFT calculated structures and energies while the capped CNTs result in comparable energies but incorrect structures compared to DFT calculations. Considering geometry optimization performed with ANN on CNTs the errors lie within 170 meV/atom (&lt; 1.8% error) with an RMSE of 20 meV/atom. For the geometry optimizations of the capped CNTs the errors are within 430 meV/atom (&lt; 5.5% error) with an RMSE of 14 meV/atom. All results are compared with empirical potentials (ReaxFF) and we find that the ANN approximated potentials are more accurate than the best tested empirical potential. This work shows that machine learning may be used to approximate DFT calculations. However, for further applications our conclusion is that the error of the estimated forces must be reduced further. Finally, we investigate the computing time (number of core hours) required and find that the ANN is about two orders of magnitude faster than DFT and three to four orders of magnitude slower than ReaxFF. For the unseen data the ANN is still around 2 orders of magnitude quicker than the DFT but here it is around 4 order of magnitude slower than ReaxFF. / <p>Supervisors: Daniel Hedman and Fredrik Sandin</p> / F7042T - Project in Engineering Physics

Condensed Matter Physics

Den kondenserade materiens fysik

Other Computer and Information Science

Annan data- och informationsvetenskap

The role of charge and orbital ordering in quadruple perovskite materials with multiferroic potential

Perks, Natasha J.

January 2015

With the overriding goal of developing functional multiferroic systems with technological potential, this thesis focuses on the role of orbital and charge ordering in coupling magnetism and ferroelectricity in synthetic quadruple perovskites. Using x-ray diffraction as the primary characterisation tool, modulations to crystal ordering have been interpreted in terms of orbital occupation and charge variation. Expanding on previous magnetic structure studies and polarisation measurements, structural analysis of CaMn₇O₁₂ has led to the experimental realisation of a new mechanism for multiferroicity, resulting from a "magneto-orbital helix". Motivated by the idea of tuning multiferroic properties through varying manganese valence, the doped system CaCu_xMn_7-xO₁₂ has been studied. Structural models considering the possibility of domain formation and multiple coexisting modulations have been tested against x-ray diffraction data. Finally, motivated by theoretical predictions of ferroelectric phases and multiferroicity in doped, simple, manganite perovskites, a structural model for the low temperature phase of NaMn₇O₁₂ has been developed, based upon theoretical predictions for orbital ordering and the experimentally determined magnetic structure. This model has been tested against previously measured neutron diffraction data. The importance of understanding crystal formation and domain structures when applying theoretical models has been highlighted, and has prompted the consideration of future work involving viewing and manipulating twin formation.

620.1