Transferts d'énergie dans des titanates dopés Pr 3+ et application au développement d'afficheurs électroluminescents par pulvérisation cathodique

Sarakha, Ludovic

03 February 2011

Ce travail de thèse est une contribution au développement d'afficheurs électroluminescents inorganiques utilisant le luminophore CaTiO3 :Pr3+ comme couche active. Il comporte deux volets. Le premier concerne l'étude du dépôt de CaTiO3 :Pr3+ par pulvérisation cathodique à partir d'une cible céramique élaborée au laboratoire et s'est plus particulièrement attaché à l'influence de la pression de dépôt et aux conditions de recuit (température, type de fours) sur les propriétés morphologiques, structurales, optiques et électriques des films. Les films obtenus sont cristallisés en structure orthorhombique, photoluminescents, transparents sur toute la gamme du visible et possèdent des propriétés électriques compatibles avec l'application visée. Des pistes d'optimisation de ces propriétés sont également avancées. Le second volet du travail utilise le modèle de transfert de charge par intervalence (TCIV) développé ces dernières années au laboratoire, pour orienter la recherche d'autres luminophores dopés par des ions Pr3+ utilisables dans des afficheurs électroluminescents. Sur cette base, des titanates de formulations (Ca,Sr)TiO3 :Pr3+, CaTiO3 :Bi3+ ;Pr3+ et Na1/2Ln1/2TiO3 :Pr3+ (Ln = La, Gd, Y, Lu) ont été synthétisés et caractérisés. L'évaluation détaillée du comportement de ces matériaux en photoluminescence a permis de valider le modèle TCIV, d'initier d'autres modèles et de mettre en évidence l'intérêt d'un codopage au bismuth pour accroître l'intensité de fluorescence de l'ion Pr3+ dans la matrice CaTiO3. Le luminophore rouge CaTiO3 :Bi3+ ; Pr3+ apparaît être un candidat intéressant pour des applications en électroluminescence.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

CaTiO3:Pr3+

Couches minces

Electroluminescence

Luminophores

Modèle TCIV

Photoluminescence

PVD

An Experimental Study to Improve the Casting Performance of Steel Grades Sensitive for Clogging

Svensson, Jennie

January 2017

In this study, the goal is to optimize the process and to reduce the clogging tendency during the continuous casting process. The focus is on clogging when the refractory base material (RBM) in the SEN is in contact with the liquid steel. It is difficult or impossible to avoid non-metallic inclusions in the liquid steel, but by a selection of a good RBM in the SEN clogging can be reduced.   Different process steps were evaluated during the casting process in order to reduce the clogging tendency. First, the preheating of the SEN was studied. The results showed that the SEN can be decarburized during the preheating process. In addition, decarburization of SEN causes a larger risk for clogging. Two types of plasma coatings were implemented to protect the RBM, to prevent reactions with the RBM, and to reduce the clogging tendency. Calcium titanate (CaTiO3) mixed with yttria stabilized zirconia (YSZ) plasma coatings were tested in laboratory and pilot plant trials, for casting of aluminium-killed low-carbon steels. For casting of cerium alloyed stainless steels, YSZ plasma coatings were tested in laboratory, pilot plant and industrial trials. The results showed that the clogging tendency was reduced when implementing both coating materials.   It is also of importance to produce clean steel in order to reduce clogging. Therefore, the steel cleanliness in the tundish was studied experimentally. The result showed that inclusions originated from the slag, deoxidation products and tundish refractory and that they were present in the tundish as well as in the final steel product. / <p>QC 20170227</p> / VINNOVA

Preheating

Decarburization

RBM

Clogging

SEN

Plasma sprayed coating

CaTiO3

YSZ

Continuous casting

Pilot plant trials

Industrial plant trials

Clean steel

Tundish

Non-metallic inclusions

MISS

Development of Multifunctional Biomaterials and Probing the Electric Field Stimulated Cell Functionality on Conducting Substrates : Experimental and Theoretical Studies

Ravikumar, K

January 2015

Materials with appropriate combinations of multifunctional properties (strength, toughness, electrical conductivity and piezoelectricity) together with desired biocompatibility are promising candidates for biomedical applications. Apart from these material properties, recent studies have shown the efficacy of electric field in altering cell functionality in order to elicit various cell responses, like proliferation, differentiation, apoptosis (programmed cell death) on conducting substrates in vitro. In the above perspective, the current work demonstrates how CaTiO3 (CT) addition to Hydroxyapatite (HA) can be utilised to obtain an attractive combination of long crack fracture toughness (up to 1.7 MPa.m1/2 measured using single edge V-notch beam technique) and a flexural strength of 155 MPa in addition to moderate electrical conductivity. The enhancement of fracture toughness in HA-CT composites has been explained based on the extensive characterization of twinned microstructure in CT along with the use of theoretical models for predicting the enhancement of toughening through crack tip tilt and twist mechanisms. Subsequent in vitro studies on HA-CT composites with human Mesenchymal Stem cells (hMSCs) in the presence of electric field has shown enhanced differentiation towards bone like cells (osteogenic lineage) as evaluated by ALP activity, Collagen content and gene expression analyses through Polymerase Chain Reaction (PCR) at the end of two weeks. he extracellular matrix mineralization analysis at the end of 4 weeks of hMSC culture further substantiated the efficacy of electric field as a biochemical cue that can influence the stem cell fate processes on conducting substrates. The electric field stimulation strategy was also implemented in in vitro studies with C2C12 mouse myoblast (muscle) cells on elastically compliant poly(vinylidene difluoride) (PVDF)-multiwall carbon nanotube (MWNT) composite substrates. PVDF is a piezoelectric polymer and the addition of MWNTs makes the composite electrically conducting. Upon, electric field stimulation of C2C12 mouse myoblast cells on these composites, has been observed that in a narrow window of electric field parameters, the cell viability was enhanced along with excellent cell alignment and cell-cell contact indicating a potential application of PVDF-based materials in the muscle cell regeneration. In an effort to rationalise such experimental observations, a theoretical model is proposed to explain the development of bioelectric stress field induced cell shape stability and deformation. A single cell is modelled as a double layered membrane separating the culture medium and the cytoplasm with different dielectric properties. This system is linearized by invoking Debye-Huckel approximation of the Poisson-Boltzmann equation. With appropriate boundary conditions, the system is solved to obtain intracellular and extracellular Maxwell stress as a function of multiple parameters like cell size, intracellular and extracellular permittivity and electric field strength. Based on the stresses, we predict shape changes of cell membrane by approximating the deformation amplitude under the influence of electric field. Apart from this, the shear stress on the membrane has been used to determine the critical electric field required to induce membrane breakdown. The analysis is conducted for a cell in suspension/on a conducting substrate and on an insulating substrate to illustrate the effect of substrate properties on cell response under the influence of external electric field.

Multi Functional Biomaterials

Mechanical Properties - Composite

Electric Field Induced Osteogenesis

HA-Metal Composites

HA-Polymer Composites

HA-Ceramic Composites

HA–CaTiO3 Composites

PVDF-MWNT Composites

poly(vinylidene difluoride) (PVDF)

Multi-walled Carbon Nanotubes (MWNTN

Hydroxyapatite- CaTiO3 Composites

Materials Science

An Experimental Study to Improve the Casting Performance of Steel Grades Sensitive for Clogging

Svensson, Jennie

January 2017

In this study, the goal is to optimize the process and to reduce the clogging tendency during the continuous casting process. The focus is on clogging when the refractory base material (RBM) in the SEN is in contact with the liquid steel. It is difficult or impossible to avoid non-metallic inclusions in the liquid steel, but by a selection of a good RBM in the SEN clogging can be reduced.   Different process steps were evaluated during the casting process in order to reduce the clogging tendency. First, the preheating of the SEN was studied. The results showed that the SEN can be decarburized during the preheating process. In addition, decarburization of SEN causes a larger risk for clogging. Two types of plasma coatings were implemented to protect the RBM, to prevent reactions with the RBM, and to reduce the clogging tendency. Calcium titanate (CaTiO3) mixed with yttria stabilized zirconia (YSZ) plasma coatings were tested in laboratory and pilot plant trials, for casting of aluminium-killed low-carbon steels. For casting of cerium alloyed stainless steels, YSZ plasma coatings were tested in laboratory, pilot plant and industrial trials. The results showed that the clogging tendency was reduced when implementing both coating materials.   It is also of importance to produce clean steel in order to reduce clogging. Therefore, the steel cleanliness in the tundish was studied experimentally. The result showed that inclusions originated from the slag, deoxidation products and tundish refractory and that they were present in the tundish as well as in the final steel product. / VINNOVA

Preheating

Decarburization

RBM

Clogging

SEN

Plasma sprayed coating

CaTiO3

YSZ

Continuous casting

Pilot plant trials

Industrial plant trials

Clean steel

Tundish

Non-metallic inclusions

MISS

Metallurgy and Metallic Materials

Metallurgi och metalliska material