Etude de la séparation de phase magnétique dans les manganites à effet CMR par diffusion de neutrons aux petits angles

Saurel, Damien

07 December 2005

Ce manuscrit présente l?étude par diffusion de neutrons aux petits angles des inhomogénéités magnétiques de l?échelle nanométrique à l?échelle mésoscopique à basse température dans les composés manganites à effet CMR de la série Pr1-xCaxMnO3, x proche de 1/3, et son évolution sous champ magnétique appliqué. <br />Ces systèmes montrent une séparation de phase à grande échelle entre une phase ferromagnétique isolante (FI) et une phase antiferromagnétique isolante (AFI) correspondant à deux phases cristallines distinctes. Ils se transforment en une troisième phase cristalline, ferromagnétique métallique (FM), sous l?effet du champ magnétique. Nous avons tenté de comprendre par quel mécanisme. <br />Nous avons mis en évidence l?existence d?inhomogénéités magnétiques nanométriques dans chacune des phases FI et AFI. Notre étude sous champ révèle l?apparition d?un fort signal de diffusion dû à une nucléation de clusters de phase FM mésoscopiques (quelques centaines de nanomètres) lors de la transition I-M induite par le champ, faisant ainsi disparaître la diffusion par les objets nanométriques. L?effet CMR n?est donc pas dû à une nucléation à l?échelle nanométrique mais mésoscopique.

[PHYS:COND] Physics/Condensed Matter

magnétisme

ferromagnétisme

antiferromagnétisme

manganite

perovskite

percolation

physique statistique

magnétorésistance

neutrons diffusion

Soluções analíticas da equação de difusão de nêutrons geral por técnicas de transformadas integrais / Analytical solutions for the general neutrons diffusion equation by integral transform techniques

Heinen, Ismael Rodrigo

January 2009

No presente trabalho são apresentadas soluções analíticas das equações de difusão de nêutrons bidimensionais com dois grupos de energia, a saber, nêutrons rápidos e térmicos em uma placa com propriedades homogêneas. Alem disso, são resolvidos detalhadamente os problemas onde a placa homogênea é substituída por duas e quatro regiões, tornando-os não-homogêneos. A partir da aplicação da transformada de Laplace e da Técnica da Transformada Integral Generalizada (GITT), respectivamente, é resolvida em uma forma analítica o problema de autovalor resultante para o fluxo de nêutrons. No problema heterogêneo são usados filtros para homogenizar as condições de contorno não-homogêneas. Esta é a condição para a aplicação da GITT. Os três problemas mencionados acima são resolvidos aplicando primeiramente a GITT, o qual reduz a dimensão da equação de difusão, seguida da aplicação da transformada de Laplace, o qual reduz a ordem da equação. Deste procedimento, resulta um sistema de equações algébricas dependente das constantes de integração. 0 sistema é resolvido usando a técnica da eliminação de Gauss. Os fluxos transformados pela GITT são recuperados invertendo-se analiticamente a transformada de Laplace usando a expansão de Heaviside, os quais ainda dependem das constantes de integração. A partir da aplicação das condições de contorno e de interface (para os problemas não-homogêneos) obtém-se um sistema de equações algébricas homogêneas, de onde é determinado o fator de multiplicação efetivo Keff pelo método da bissecção. As constantes de integração são determinadas fazendo use da potencia prescrita da placa. Assim, os fluxos de nêutrons transformados pela GITT ficam determinados e os fluxos de nêutrons rápidos e térmicos são recuperados através da formula da inversa da GITT, usando a expansão do potencial. Resultados são comparados com a solução do método de diferenças finitas. / In the present work we present analytical solutions of the bi-dimensional neutron diffusion equation with two energy groups, i.e. fast and thermal neutrons in a sheet with homogeneous properties. Further we solve the detailed problem where the homogeneous sheet is substituted by two and four regions, rendering the problem a non-homogeneous one. Upon application of the Laplace transform and Generalized Integral Transform Tecnique (GITT), respectively, we solve in an analytical fashion the resulting eigenvalue problem for the neutron flux. In the heterogeneous problem, we use filter functions in order to homogenize the non-homogeneous boundary conditions. This is a condition for the application of GITT. We solve the three problems mentioned above applying first GITT, which reduces the dimension of the diffusion equation followed by the Laplace transform, which reduces the order of the equation. This procedure yields a non-homogeneous algebraic system depending on integration constants. The system is solved using the elimination technique by Gauss. The transformed fluxes by GITT are recovered upon inverting analytically the Laplace transform using Heaviside's expansion which depend still on the integration constants. Upon application of the boundary and interface conditions (for the non-homogeneous problem) one obtains a system of homogeneous algebraic equations, where we determine the effective multiplication factor keff by the bisection method. The integration constants are determined making use of the predefined power of the sheet. Thus the neutron fluxes transformed by GITT are determined and the fast and thermal neutron flux are recovered by the inverse formula of GITT, using the potential expansion. Results are compared to the solution by the finite difference method.

Transformada de Laplace

Fenômenos de transporte

Métodos numéricos

Analytical solutions

Neutrons diffusion equation

GITT

Laplace transform

Soluções analíticas da equação de difusão de nêutrons geral por técnicas de transformadas integrais / Analytical solutions for the general neutrons diffusion equation by integral transform techniques

Heinen, Ismael Rodrigo

January 2009

No presente trabalho são apresentadas soluções analíticas das equações de difusão de nêutrons bidimensionais com dois grupos de energia, a saber, nêutrons rápidos e térmicos em uma placa com propriedades homogêneas. Alem disso, são resolvidos detalhadamente os problemas onde a placa homogênea é substituída por duas e quatro regiões, tornando-os não-homogêneos. A partir da aplicação da transformada de Laplace e da Técnica da Transformada Integral Generalizada (GITT), respectivamente, é resolvida em uma forma analítica o problema de autovalor resultante para o fluxo de nêutrons. No problema heterogêneo são usados filtros para homogenizar as condições de contorno não-homogêneas. Esta é a condição para a aplicação da GITT. Os três problemas mencionados acima são resolvidos aplicando primeiramente a GITT, o qual reduz a dimensão da equação de difusão, seguida da aplicação da transformada de Laplace, o qual reduz a ordem da equação. Deste procedimento, resulta um sistema de equações algébricas dependente das constantes de integração. 0 sistema é resolvido usando a técnica da eliminação de Gauss. Os fluxos transformados pela GITT são recuperados invertendo-se analiticamente a transformada de Laplace usando a expansão de Heaviside, os quais ainda dependem das constantes de integração. A partir da aplicação das condições de contorno e de interface (para os problemas não-homogêneos) obtém-se um sistema de equações algébricas homogêneas, de onde é determinado o fator de multiplicação efetivo Keff pelo método da bissecção. As constantes de integração são determinadas fazendo use da potencia prescrita da placa. Assim, os fluxos de nêutrons transformados pela GITT ficam determinados e os fluxos de nêutrons rápidos e térmicos são recuperados através da formula da inversa da GITT, usando a expansão do potencial. Resultados são comparados com a solução do método de diferenças finitas. / In the present work we present analytical solutions of the bi-dimensional neutron diffusion equation with two energy groups, i.e. fast and thermal neutrons in a sheet with homogeneous properties. Further we solve the detailed problem where the homogeneous sheet is substituted by two and four regions, rendering the problem a non-homogeneous one. Upon application of the Laplace transform and Generalized Integral Transform Tecnique (GITT), respectively, we solve in an analytical fashion the resulting eigenvalue problem for the neutron flux. In the heterogeneous problem, we use filter functions in order to homogenize the non-homogeneous boundary conditions. This is a condition for the application of GITT. We solve the three problems mentioned above applying first GITT, which reduces the dimension of the diffusion equation followed by the Laplace transform, which reduces the order of the equation. This procedure yields a non-homogeneous algebraic system depending on integration constants. The system is solved using the elimination technique by Gauss. The transformed fluxes by GITT are recovered upon inverting analytically the Laplace transform using Heaviside's expansion which depend still on the integration constants. Upon application of the boundary and interface conditions (for the non-homogeneous problem) one obtains a system of homogeneous algebraic equations, where we determine the effective multiplication factor keff by the bisection method. The integration constants are determined making use of the predefined power of the sheet. Thus the neutron fluxes transformed by GITT are determined and the fast and thermal neutron flux are recovered by the inverse formula of GITT, using the potential expansion. Results are compared to the solution by the finite difference method.

Transformada de Laplace

Fenômenos de transporte

Métodos numéricos

Analytical solutions

Neutrons diffusion equation

GITT

Laplace transform

Soluções analíticas da equação de difusão de nêutrons geral por técnicas de transformadas integrais / Analytical solutions for the general neutrons diffusion equation by integral transform techniques

Heinen, Ismael Rodrigo

January 2009

No presente trabalho são apresentadas soluções analíticas das equações de difusão de nêutrons bidimensionais com dois grupos de energia, a saber, nêutrons rápidos e térmicos em uma placa com propriedades homogêneas. Alem disso, são resolvidos detalhadamente os problemas onde a placa homogênea é substituída por duas e quatro regiões, tornando-os não-homogêneos. A partir da aplicação da transformada de Laplace e da Técnica da Transformada Integral Generalizada (GITT), respectivamente, é resolvida em uma forma analítica o problema de autovalor resultante para o fluxo de nêutrons. No problema heterogêneo são usados filtros para homogenizar as condições de contorno não-homogêneas. Esta é a condição para a aplicação da GITT. Os três problemas mencionados acima são resolvidos aplicando primeiramente a GITT, o qual reduz a dimensão da equação de difusão, seguida da aplicação da transformada de Laplace, o qual reduz a ordem da equação. Deste procedimento, resulta um sistema de equações algébricas dependente das constantes de integração. 0 sistema é resolvido usando a técnica da eliminação de Gauss. Os fluxos transformados pela GITT são recuperados invertendo-se analiticamente a transformada de Laplace usando a expansão de Heaviside, os quais ainda dependem das constantes de integração. A partir da aplicação das condições de contorno e de interface (para os problemas não-homogêneos) obtém-se um sistema de equações algébricas homogêneas, de onde é determinado o fator de multiplicação efetivo Keff pelo método da bissecção. As constantes de integração são determinadas fazendo use da potencia prescrita da placa. Assim, os fluxos de nêutrons transformados pela GITT ficam determinados e os fluxos de nêutrons rápidos e térmicos são recuperados através da formula da inversa da GITT, usando a expansão do potencial. Resultados são comparados com a solução do método de diferenças finitas. / In the present work we present analytical solutions of the bi-dimensional neutron diffusion equation with two energy groups, i.e. fast and thermal neutrons in a sheet with homogeneous properties. Further we solve the detailed problem where the homogeneous sheet is substituted by two and four regions, rendering the problem a non-homogeneous one. Upon application of the Laplace transform and Generalized Integral Transform Tecnique (GITT), respectively, we solve in an analytical fashion the resulting eigenvalue problem for the neutron flux. In the heterogeneous problem, we use filter functions in order to homogenize the non-homogeneous boundary conditions. This is a condition for the application of GITT. We solve the three problems mentioned above applying first GITT, which reduces the dimension of the diffusion equation followed by the Laplace transform, which reduces the order of the equation. This procedure yields a non-homogeneous algebraic system depending on integration constants. The system is solved using the elimination technique by Gauss. The transformed fluxes by GITT are recovered upon inverting analytically the Laplace transform using Heaviside's expansion which depend still on the integration constants. Upon application of the boundary and interface conditions (for the non-homogeneous problem) one obtains a system of homogeneous algebraic equations, where we determine the effective multiplication factor keff by the bisection method. The integration constants are determined making use of the predefined power of the sheet. Thus the neutron fluxes transformed by GITT are determined and the fast and thermal neutron flux are recovered by the inverse formula of GITT, using the potential expansion. Results are compared to the solution by the finite difference method.

Transformada de Laplace

Fenômenos de transporte

Métodos numéricos

Analytical solutions

Neutrons diffusion equation

GITT

Laplace transform

Caractérisation de la liaison hydrogène dans des systèmes moléculaires d'intérêt biologique par diffusion de neutrons

Cavillon, François

01 October 2004

Ce travail présente une méthodologie pour l'analyse des spectres de diffusion de neutron sur des liquides moléculaires, basée sur l'ajustement du facteur de forme moléculaire aux grands transferts de moment. La soustraction des contributions intramoléculaires permet d'isoler les interactions intermoléculaires telles que la liaison hydrogène. Trois systèmes de complexité croissante sont étudiés : l'ammoniac, la N-méthylformamide et la N-méthylacétamide. Les résultats obtenus sur l'ammoniac valident la méthode. La liaison hydrogène est bien caractérisée, à une longueur remettant en cause les valeurs habituellement trouvées dans la littérature. Ces résultats ont été confirmés par une étude utilisant la substitution isotopique N14/N1S. L'ajustement de la moléculede NMF est obtenu avec une bonne précision. La caractérisation de la liaison hydrogène y est toutefois plus délicate. Une étude préliminaire de la NMA liquide montre qu'il est possible d'obtenir de bons résultats avec des molécules complexes.

[PHYS] Physics

liaisons hydrogène

neutrons -- diffusion

ammoniac liquide

liquides moléculaires

N-méthylformamide

N-méthylacétamide

systèmes moléculaires

substitution isotopique

Solution of algebraic problems arising in nuclear reactor core simulations using Jacobi-Davidson and multigrid methods

Havet, Maxime

10 October 2008

The solution of large and sparse eigenvalue problems arising from the discretization of the diffusion equation is considered. The multigroup<p>diffusion equation is discretized by means of the Nodal expansion Method (NEM) [9, 10]. A new formulation of the higher order NEM variants revealing the true nature of the problem, that is, a generalized eigenvalue problem, is proposed. These generalized eigenvalue problems are solved using the Jacobi-Davidson (JD) method<p>[26]. The most expensive part of the method consists of solving a linear system referred to as correction equation. It is solved using Krylov subspace methods in combination with aggregation-based Algebraic Multigrid (AMG) techniques. In that context, a particular<p>aggregation technique used in combination with classical smoothers, referred to as oblique geometric coarsening, has been derived. Its particularity is that it aggregates unknowns that<p>are not coupled, which has never been done to our<p>knowledge. A modular code, combining JD with an AMG preconditioner, has been developed. The code comes with many options, that have been tested. In particular, the instability of the Rayleigh-Ritz [33] acceleration procedure in the non-symmetric case has been underlined. Our code has also been compared to an industrial code extracted from ARTEMIS. / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Physique

Nuclear energy

Nuclear reactors -- Simulation methods

Neutron flux

Neutrons -- Scattering

Energie nucléaire

Flux de neutrons

Neutrons -- Diffusion

Algebraic Multigrid

Aggregation

Nodal Expansion Method

Krylov

eigenvalue problem

preconditioning

Jacobi-Davidson

Contribution de la simulation sur ordinateur à l'interprétation d'expériences spectroscopiques sondant la dynamique locale de fondus de polymères

Arialdi, Gianluigi

12 September 2003

<p align="justify">Une contribution à l'étude de la dynamique des polymères non enchevêtrés à l'état fondu est apportée, en se focalisant sur les aspects de dynamique locale d'un polymère particulier déjà fort étudié expérimentalement et par simulation, à savoir le polyéthylène.</p> <p><p align="justify">Néanmoins, plusieurs nouveaux résultats spécifiques à cette macromolécule linéaire ou ayant une portée sur les fondus de polymères en général sont obtenus grâce à une approche présentant plusieurs aspects originaux.</p><p><p align="justify">Notre étude par simulation de la phase liquide du polyéthylène est menée sur une large gamme de températures. La nouveauté principale à ce sujet est l'attention particulière portée à la qualité d'équilibration des échantillons à chaque température. A cette fin, des techniques sophistiquées d'échantillonnage Monte Carlo, mises au point récemment, ont été utilisées pour générer des configurations initiales, la phase de polyéthylène à l'état fondu ainsi obtenue pouvant être stable ou métastable. Un programme original de Dynamique Moléculaire a par ailleurs été écrit, en incorporant diverses procédures d'optimisation adaptées au cas du polyéthylène représenté par un modèle atomistique.</p><p><p align="justify">Des observables de diffusion quasi-élastique de neutrons et de résonance magnétique nucléaire sont analysées sur base d'une combinaison linéaire continue d'exponentielles, dont les poids sont donnés par une distribution des temps de relaxation. Cette méthode permet de mieux mettre en évidence les différents processus de relaxation sondés, en évitant les biais induits par un choix particulier de forme analytique servant à une procédure d'ajustement.</p><p><p align="justify">Ayant participé à une expérience de spectroscopie par temps de vol de neutrons, un schéma commun d'analyse est adopté pour les données expérimentales et de simulation concernant le polyéthylène à 450 K. D'autre part, une étude très fouillée de l'évolution de la fonction de diffusion intermédiaire incohérente vers les températures plus basses, suivie par simulation, a permis de distinguer différents processus dynamiques et de déterminer parfois leur origine moléculaire.</p><p><p align="justify">Ces résultats sont combinés à une analyse de la fonction d'auto corrélation d'orientation d'un vecteur C-H en termes d'une description microscopique des processus dynamiques, proposée lors d'une étude récente de fondus de polyéthylène par résonance magnétique nucléaire du 13C. Deux approches complémentaires sont exploitées afin de révéler les caractéristiques essentielles des deux types de relaxation impliqués.</p><p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Physique

Nuclear magnetic resonance

Polymers

Glass transition temperature

Condensed matter

Neutrons -- Scattering

Résonance magnétique nucléaire

Polymères

Température de transition vitreuse

Matière condensée

Neutrons -- Diffusion

Diffusion de neutrons

Spectroscopie (état condensé)

Transition vitreuse

Prop. thermiques

Physique de l'état condensé

Etat fondu

Dynamique moléculaire

Étude des propriétés électriques et structurales de verres de sulfures au lithium pour électrolytes de batteries tout-solide / Electrical and structural properties of Li-sulfide glasses as electrolytes for all-solid-state batteries

Cozic, Solenn

15 September 2016

Le marché du stockage de l'énergie est en perpétuelle expansion, tant pour les applications nomades que fixes. Afin de répondre aux exigences requises pour les diverses applications (appareils électroniques, véhicules hybrides et électriques, stockage des énergies renouvelables…), des batteries toujours plus performantes, compactes et légères doivent être développées. Pour cela, les batteries utilisant du lithium métallique en tant qu'anode sont les plus attractives en termes de densités d'énergies. Néanmoins, l'utilisation d'électrolytes liquides conventionnels, généralement des solvants organiques inflammables, dans de tels dispositifs soulève des problématiques de sécurité. Les travaux de recherche présentés dans ce manuscrit concernent l'étude de matériaux vitreux pouvant être utilisés en tant qu'électrolyte solide afin de permettre le développement de batteries tout-solide sûres et performantes. Des verres de sulfures au lithium, attractifs pour leurs propriétés de conduction ionique, sont étudiés et caractérisés. Les propriétés de conduction ionique dans les verres étant toujours mal comprises et sujettes à controverses, l'analyse structurale des verres présente ici un réel intérêt pour une meilleure compréhension des corrélations entre structure et propriétés. Un effort de recherche a donc été porté sur l'étude de l'ordre local dans les verres préparés via différentes techniques d'analyse structurale complémentaires. Enfin, les matériaux vitreux, sont de manière générale relativement faciles à mettre en forme. Les verres étudiés dans ce manuscrit peuvent alors également être utilisés en tant qu'électrolytes sous forme de couches minces dans les micro-batteries. Des premiers essais de dépôts par pulvérisation cathodique RF magnétron de couches minces conductrices ont donc été effectués et constituent la première brique à la fabrication de micro-batteries. / The energy storage market is in constant growth for both portable and stationary applications. To satisfy the requirements of various applications (electronic devices, hybrid-electric vehicles, renewable energy storage…), always more efficient, more compact and lightweight batteries have to be developed. Then, thanks to their high energy densities, batteries using Li metal anodes are the most promising to complete this challenge. However, the use of conventional liquid electrolytes raises safety issues, mainly related to the flammability of the organic liquid. In this thesis, glassy materials, exhibiting great interest towards developing solid electrolytes are considered and might enable the development of safe and efficient all-solid-state batteries. Here, Li-sulfide glasses, attractive for their ionic conduction properties, have been studied and characterized. The ionic conduction properties of glasses are still misunderstood and controversial, the structural investigation of glasses is of great interest in order to get a better understanding of structure-properties relationship. Then, the short and intermediate range order of prepared glasses have been investigated by the mean of various complementary structural analysis techniques. Finally, glassy materials are usually quite easy to shape. Thus, studied glasses in this thesis can also be used as thin-film electrolytes in microbatteries. First tests of sputtering of conducting thin-films have been performed by RF magnetron sputtering and constitute a first step in order to design microbatteries.

Verres de chalcogénure

Conduction ionique

Structure de la matière

Couche mince

Pulvérisation cathodique RF magnétron

Électrolyte

Spectroscopie Raman

Batteries tout-Solide

Accumulateurs au lithium

Chalcogenide glasses

Lithium

Ionic conductivity

Short-Range structure

Thin-Film

RF magnetron sputtering

Electrolyte

Impedance spectroscopy

All-Solid-State batteries

Neutron diffraction

X-Ray diffraction

Raman spectroscopy