The structure and thermal evolution of metakaolin geopolymers

Duxson, Peter

Unknown Date

Geopolymers are a relatively new class of material that has many broad applications, including use as a substitute for Ordinary Portland Cement (OPC), use in soil stabilisation, fire resistant panels, refractory cements, and inorganic adhesives. The synthetic alkali aluminosilicate structure of geopolymer results in a highly versatile material that can be synthesised en masse, cost competitively and from a wide varietyof aluminosilicate bearing raw materials. / Despite the commercial promise and technical viability of the technology, the fundamental understanding of the chemical structure and characteristics of geopolymeric materials, and to some degree the academic rigor of some aspects of the science related to geopolymers, leave a lot to be desired. In particular, the understanding of the effects of Si/Al ratio and alkali cation type on the molecular structure of the binder, and how these relate to the microstructure and mechanical and thermal properties are poorly understood. / The thesis explores the structure and characteristics of a systematic multi-dimensional matrix of geopolymers derived from metakaolin, a relatively pure aluminosilicate source. The thesis addresses the determination of the core molecular structure of geopolymers by solid-state NMR spectroscopy, and how this is altered by the nominal Si/Al ratio and alkali cation type. The chemical ordering is observed to reduce with Si/Al ratio and with inclusion of potassium over sodium. Most significantly, the presence of Al-O-Al linkages is identified for the first time in specimens with Si/Al ratios close to unity, by the application of 17O NMR techniques on geopolymers. The role of molecular structure and gel chemistry of geopolymers is elucidated, and links are drawn to understand the development of the microstructure and physical properties of the material. The thermal evolution of geopolymeric gels derived from metakaolin is investigated in terms of physical and structural development when exposed to temperatures up to 1000°C. The response of geopolymers to heating is characterised into four regions regardless of the extent of shrinkage or crystallisation. Several critical material performance relationships exist that are related to both the microstructure and chemical composition. / The thesis presents an updated structural model of geopolymers to include new insights obtained from application of solid-state NMR techniques and thermal analysis. The improvements in structural understanding described in the thesis have the potential to affect all aspects of geopolymer science.

Novel Materials and Processing Routes Using Alkali-activated Systems

January 2019

abstract: This dissertation aims at developing novel materials and processing routes using alkali activated aluminosilicate binders for porous (lightweight) geopolymer matrices and 3D-printing concrete applications. The major research objectives are executed in different stages. Stage 1 includes developing synthesis routes, microstructural characterization, and performance characterization of a family of economical, multifunctional porous ceramics developed through geopolymerization of an abundant volcanic tuff (aluminosilicate mineral) as the primary source material. Metakaolin, silica fume, alumina powder, and pure silicon powder are also used as additional ingredients when necessary and activated by potassium-based alkaline agents. In Stage 2, a processing route was developed to synthesize lightweight geopolymer matrices from fly ash through carbonate-based activation. Sodium carbonate (Na2CO3) was used in this study to produce controlled pores through the release of CO2 during the low-temperature decomposition of Na2CO3. Stage 3 focuses on 3D printing of binders using geopolymeric binders along with several OPC-based 3D printable binders. In Stage 4, synthesis and characterization of 3D-printable foamed fly ash-based geopolymer matrices for thermal insulation is the focus. A surfactant-based foaming process, multi-step mixing that ensures foam jamming transition and thus a dry foam, and microstructural packing to ensure adequate skeletal density are implemented to develop foamed suspensions amenable to 3D-printing. The last stage of this research develops 3D-printable alkali-activated ground granulated blast furnace slag mixture. Slag is used as the source of aluminosilicate and shows excellent mechanical properties when activated by highly alkaline activator (NaOH + sodium silicate solution). However, alkali activated slag sets and hardens rapidly which is undesirable for 3D printing. Thus, a novel mixing procedure is developed to significantly extend the setting time of slag activated with an alkaline activator to suit 3D printing applications without the use of any retarding admixtures. This dissertation, thus advances the field of sustainable and 3D-printable matrices and opens up a new avenue for faster and economical construction using specialized materials. / Dissertation/Thesis / Doctoral Dissertation Civil, Environmental and Sustainable Engineering 2019

Civil engineering

Environmental engineering

Sustainability

3D-printing

Additive Manufacturing

Alkali-activation

Aluminosilicate

Geopolymer

Porous Ceramic

Etude structurale d’aluminosilicates de calcium : application à la valorisation de déchets amiantés pour le stockage thermique d’énergie solaire / Structural characterization of calcium aluminosilicates : development of asbestos-containing wastes ceramics for thermal storage of solar energy

Lambert, Julien

12 April 2013

L’objectif de ce travail de thèse est d’établir les relations entre les propriétés structurales et les conditions d’élaboration d’un vitrifiat de déchets amiantés (nom commercial Cofalit®), dans la perspective de fabriquer un prototype de module de stockage thermique d’énergie solaire. Malgré des provenances de déchets très diverses, les variations de compositions du vitrifiat restent limitées. Les conditions d’élaboration (de refroidissement en particulier) induisent par contre d’importantes disparités dans la microstructure. L’analyse d’une carotte de Cofalit nous a permis de déterminer les mécanismes de cristallisation lors de la fabrication du Cofalit (refroidissement non contrôlé), conduisant à un mélange de phases cristallisées et vitreuse. Nous avons étudié les propriétés structurales (par DRX et RMN) et de cristallisation d’échantillons modèles représentatifs du matériau industriel. Les variations de composition observées sur celui-ci ont été simulées par des ajouts de silice ou de chaux. L’influence de la teneur en fer sur les propriétés radiatives, structurales (verres et céramiques) et de cristallisation a également été quantifiée. Le suivi de la cristallisation séquentielle des céramiques a été effectué par DRX in situ à haute température, à partir de l’état vitreux et à partir de l’état liquide lors du refroidissement. Ces essais ont montré que le Cofalit cristallise complètement pour des vitesses de refroidissement inférieures à 10 K/min. La stabilité du Cofalit (au niveau structural) lors de recuits à hautes températures a également été démontrée. / The aim of this work is to establish relationships between structural properties and production conditions of a vitrified asbestos-containing wastes ceramics (commercially named Cofalit®), with the goal of elaborating a prototype for thermal energy storage of solar energy. Despite various waste sources, the variations of composition observed for this material are limited. On the contrary, the production conditions (cooling stage in particular) induce important differences in the material microstructure. The analysis of a Cofalit core sample allowed us to determine the crystallisation mechanisms during its fabrication process (uncontrolled cooling), leading to a mixture of vitreous and crystalline phases. We propose a structural study (by XRD and NMR) and crystallization properties analyses of synthetic samples, representative of the industrial material. Observed variations of composition on the latter are simulated by additions of silica and lime. The influence of iron oxide content on radiative, structural and crystallization properties (of both glass and ceramic samples) have also been investigated. The following of the sequential crystallisation of ceramic samples has finally been performed using in situ high temperature XRD, from glassy state and during cooling from liquid state. These tests show that the Cofalit crystallizes completely for rates lower than 10 K/min. The high temperature stability on a structural level has also been demonstrated during annealings.

Aluminosilicate de calcium

Verre

Céramique

Amiante

Cofalit

Cristallisation

DRX in situ haute température

RMN (29Si et 27Al)

Stockage thermique

Energie solaire

Calcium aluminosilicate

Glass

Ceramic

Asbestos

Cofalit

Crystallization

High temperature in situ XRD

NMR (29Si et 27Al)

Thermal storage

Solar energy

Wettability of solid metals by low melting non-metallic inclusions

Parry, Gavin Wayne, Materials Science & Engineering, Faculty of Science, UNSW

January 2007

A project studied wetting of iron, nickel and platinum by molten MnO-SiO2 (MS) and CaO-Al2O3-SiO2 (CAS) slags of eutectic composition to contribute to understanding of wetting behaviour of solid metal-molten oxide systems relevant to steelmaking. Novel results of dynamic wetting behaviour by the sessile drop method were obtained under strongly reducing atmosphere (oxygen partial pressure 10-20 -- 10-18 atm). Terminal contact angles (after 240 min) for MS slag were: for iron substrates -5??2??(1350??C), 9+-2?? (1390??C), 6+-2 (1450??C); nickel -- 3+-2??(1350 and 1390??C); and platinum --15+-2??(1350 and 1390??C), 12+-2??(1450??C). Contact angles with CAS slag were: iron -- 55+-2??(1350??C), 60+-2?? (1390??C), 44+-2?? (1450??C); nickel -- 59+-2??(1350??C), 60+-2?? (1390??C); and platinum -- 15+-2?? (1350, 1390 and 1450??C). Values for interfacial tension, work of adhesion, spreading parameter (S) and interaction coefficient (Ф) were also determined. Work of adhesion for all three substrates with MS slag changed in a very narrow range 910 - 930 mJ/m2. Interfacial tension with this slag was 1,480 mN/m for Ni at 1350-1390??C, and 1,880-1,890 mN/m for Pt in the temperature range 1,350-1,450??C. For iron, interfacial tension was 1,720 mN/m at 1350??C (γ-Fe); it decreased to 1590-1580 mN/m with increasing temperature to 1390 and 1450??C (-Fe). Lower work of adhesion and higher interfacial tension was found for metals with CAS slag. Wetting properties of Pt substrate with MS slag were close to that with CAS slag, while Fe and Ni substrates showed better wetting by MS slag in comparison with CAS slag. This was attributed to higher reactivity of Fe and Ni with MS slag, particularly reduction of MnO. Although MnO was also reduced in reaction with Pt, oxygen adsorption in contact with both slags was a major factor governing wettability of Pt. Dissolution of manganese in nickel and platinum substrates at elevated temperatures modified the interface chemistry, causing formation of a liquid alloy phase. Degree of silica reduction from MS slag was much smaller in comparison with MnO reduction (negligible for Pt); it was very minor from CAS slag. Concentration profiles of Mn and Si across the interface and along the metal surface were used to estimate diffusion coefficients. Diffusion along metal surfaces was generally higher by 1 to 2 orders of magnitude than across the interface. Reduction of oxides and adsorption of oxygen modify the metal-oxide interface, making wetting dynamic. They have a profound on interfacial properties.

Wettability.

Wetting.

Nickel.

Platinum.

Manganese silicate.

Calcium aluminosilicate.

Surface tension.

Surface chemistry.

Adhesion.

Contact angle.

Steel -- Inclusions.

Physico-chimie et rhéologie de géopolymères frais pour la cimentation des puits pétroliers

Bourlon, Arnaud

14 December 2010

Les géopolymères apparaissent comme une alternative potentielle aux liants hydrauliques classiques. Ces aluminosilicates alcalins sont des matériaux amorphes produits à partir de métakaolin, ou de cendres volantes réagissant avec une liqueur d'hydroxyde, ou de silicate alcalin. Cette thèse a pour but d'évaluer le potentiel des géopolymères pour la construction des puits de pétrole. Il s'agit de combler un déficit de caractérisation et de compréhension sur le comportement rhéologique, et sur l'évolution mécanique et chimique, du gâchage à la prise des géopolymères. Pour ce faire, des méthodes aussi diverses que la RMN, le SAXS, la DLS et l'USWR ont été mobilisées pour expliquer les observations rhéologiques et mécaniques. Dans un premier temps, nous avons étudié la viscosité d'un des réactifs de la géopolymérisation : la liqueur alcaline. Nous avons montré que les variations de viscosité peuvent être expliquées par des considérations de volumes effectifs des espèces en solution. Les variations de ces volumes effectifs en fonction de la composition peuvent être rationalisées en invoquant le phénomène de volume d'excès molaire, lié à la solvatation des ions, ainsi que l'organisation de la liqueur en paires d'ions. Une fois la viscosité de la liqueur connue, il est possible de suivre l'évolution des propriétés rhéologiques de la suspension de métakaolin lors des premières heures de la réaction, en fonction de la composition et de la température. Finalement, un suivi combiné de la dissolution du métakaolin par RMN du solide et du développement des propriétés mécaniques de la matrice géopolymère du gâchage au durcissement par USWR nous a permis de conclure au caractère limitant de l'étape de dissolution du métakaolin.

Géopolymère

Aluminosilicate

Métakaolinite

Silicate

Rhéologie

Viscosité

RMN 29Si

RMN 27Al

USWR

Cimentation

Puits

Modélisation des verres d 'aluminosilmicates de calcium par dynamique moléculaire : Structure et dynamique.

Bouhadja, Mohammed

26 September 2013

Ce travail a pour but d'étudier les propriétés structurales et dynamiques des verres aluminosilicate de calcium CaO-Al2O3-SiO2 (CAS) par dynamique moléculaire classique, à partir d'un potentiel empirique de type Born-Mayer-Huggins, construit sur la base de résultats de dynamique moléculaire ab initio (AIMD) et expérimentaux. Il montre de bonnes propriétés de transférabilité sur toutes les concentrations pour les propriétés structurales et dynamiques étudiées. L'évolution des propriétés structurales a été étudiée en fonction de la température et de la concentration en silice pour trois rapports de concentrations R = [CaO]/[Al2O3]= 1, 1.57 et 3. Les résultats révèlent la présence d'oxygènes non-pontants et tricoordonnés et d'aluminium penta-coordonnés pour toutes les concentrations dont le nombre diminue avec l'augmentation avec la concentration en silice. L'étude de la viscosité et du temps de relaxation structural avec la température a permis de montrer que la fragilité diminue avec l'augmentation de la concentration en silice pour les trois valeurs de R. Une corrélation avec l'évolution des oxygènes non pontant indique que ces derniers jouent un rôle prépondérant pour la fragilité. Il est montré que la théorie des couplages de modes s'applique à la dynamique des CAS et qu'une violation de la relation de Stokes-Einstein se produit au-dessus du point de fusion expérimental indiquant une hétérogénéité dynamique.

[SPI:OTHER] Engineering Sciences/Other

Aluminosilicate de calcium

Diffusion

Viscosité

Fragilité

Potentiel BMH

Dynamique moléculaire

Wettability of solid metals by low melting non-metallic inclusions

Parry, Gavin Wayne, Materials Science & Engineering, Faculty of Science, UNSW

January 2007

A project studied wetting of iron, nickel and platinum by molten MnO-SiO2 (MS) and CaO-Al2O3-SiO2 (CAS) slags of eutectic composition to contribute to understanding of wetting behaviour of solid metal-molten oxide systems relevant to steelmaking. Novel results of dynamic wetting behaviour by the sessile drop method were obtained under strongly reducing atmosphere (oxygen partial pressure 10-20 -- 10-18 atm). Terminal contact angles (after 240 min) for MS slag were: for iron substrates -5??2??(1350??C), 9+-2?? (1390??C), 6+-2 (1450??C); nickel -- 3+-2??(1350 and 1390??C); and platinum --15+-2??(1350 and 1390??C), 12+-2??(1450??C). Contact angles with CAS slag were: iron -- 55+-2??(1350??C), 60+-2?? (1390??C), 44+-2?? (1450??C); nickel -- 59+-2??(1350??C), 60+-2?? (1390??C); and platinum -- 15+-2?? (1350, 1390 and 1450??C). Values for interfacial tension, work of adhesion, spreading parameter (S) and interaction coefficient (Ф) were also determined. Work of adhesion for all three substrates with MS slag changed in a very narrow range 910 - 930 mJ/m2. Interfacial tension with this slag was 1,480 mN/m for Ni at 1350-1390??C, and 1,880-1,890 mN/m for Pt in the temperature range 1,350-1,450??C. For iron, interfacial tension was 1,720 mN/m at 1350??C (γ-Fe); it decreased to 1590-1580 mN/m with increasing temperature to 1390 and 1450??C (-Fe). Lower work of adhesion and higher interfacial tension was found for metals with CAS slag. Wetting properties of Pt substrate with MS slag were close to that with CAS slag, while Fe and Ni substrates showed better wetting by MS slag in comparison with CAS slag. This was attributed to higher reactivity of Fe and Ni with MS slag, particularly reduction of MnO. Although MnO was also reduced in reaction with Pt, oxygen adsorption in contact with both slags was a major factor governing wettability of Pt. Dissolution of manganese in nickel and platinum substrates at elevated temperatures modified the interface chemistry, causing formation of a liquid alloy phase. Degree of silica reduction from MS slag was much smaller in comparison with MnO reduction (negligible for Pt); it was very minor from CAS slag. Concentration profiles of Mn and Si across the interface and along the metal surface were used to estimate diffusion coefficients. Diffusion along metal surfaces was generally higher by 1 to 2 orders of magnitude than across the interface. Reduction of oxides and adsorption of oxygen modify the metal-oxide interface, making wetting dynamic. They have a profound on interfacial properties.

Wettability.

Wetting.

Nickel.

Platinum.

Manganese silicate.

Calcium aluminosilicate.

Surface tension.

Surface chemistry.

Adhesion.

Contact angle.

Steel -- Inclusions.

Comportement de l’uranium et de ses simulants dans les verres d’aluminosilicates en contact avec des métaux fondus / Behavior of uranium and its surrogates in molten aluminosilicate glasses in contact with liquid metals

Chevreux, Pierrick

02 December 2016

Ce travail s’inscrit dans le cadre du développement d’un procédé innovant de conditionnement de déchets nucléaires contenant des métaux contaminés en actinides. Le principe de ce procédé consiste à incorporer des concentrations élevées en actinides dans un bain de verre au contact de métaux fondus. Parmi eux, l’aluminium et/ou l’acier inoxydable imposent un environnement très réducteur et induisent des phénomènes d’oxydoréduction au sein du verre. Ces phénomènes provoquent un changement du degré d’oxydation des actinides qui modifie leur solubilité dans le verre et peut potentiellement entraîner leur réduction à l’état métallique. Afin de mieux comprendre les processus mis en jeu, cette étude va s’intéresser au comportement de l’uranium et de ses simulants à savoir l’hafnium et le néodyme, dans des verres aluminosilicatés du système Na2O-CaO-SiO2-Al2O3 et élaborés en conditions très réductrices. La première partie de ce manuscrit est consacrée à l’étude comparative des solubilités de l’uranium et de l’hafnium dans le verre en fonction des conditions redox et de la composition du verre. Pour cela, une méthodologie a été mise en place et un montage spécifique a été utilisé afin d’imposer la fugacité en oxygène et de contrôler la teneur en alcalins du verre. Les résultats indiquent que la solubilité de l’uranium dans le verre est très inférieure à celle de l’hafnium (HfIV) dans des conditions réductrices. Pour des fugacités en oxygène inférieures à 10-14 atm, la solubilité de l’uranium est comprise entre 4 et 7 % massiques d’UO2 dans la gamme de températures de 1250°C-1400°C. L’étude de la spéciation de l’uranium par spectroscopie d’absorption des rayons X (XANES) montre que l’uranium est majoritairement présent sous la forme UIV dans le verre pour de telles fugacités en oxygène imposées. Dans la seconde partie de ce travail, les mécanismes d’interactions verre-métal ont été identifiés afin de localiser l’uranium ainsi que ses simulants (néodyme et hafnium) dans le système verre-métal. Ces mécanismes sont principalement gouvernés par la présence d’aluminium métal et sont similaires pour l’uranium et ses simulants. Dans des conditions particulières, le suivi cinétique des expériences met en évidence la présence transitoire de l’uranium et de ses simulants à l’état métallique dans des alliages ou des composés définis. Au cours du temps, une ré-oxydation de ces éléments métalliques a lieu en accord avec les données thermodynamiques. Dans le cas de l’uranium, le processus de ré-oxydation reste à confirmer. Enfin, une approche thermodynamique à l’aide des diagrammes de phases a permis d’expliquer la formation et la dissolution des différentes phases cristallines présentes au sein du verre lors des interactions verre-métal / This study concerns an innovative process used for conditioning nuclear waste that contain metallic parts contaminated with actinides. High actinides concentrations are expected to be incorporated in the glass melt in contact with the molten metals. Among these metals, aluminum and/or stainless steel impose a strongly reducing environment to the glass melt involving redox reactions. These reactions modify actinides oxidation states and therefore change their solubilities in the glass and could also reduce them into the metallic form. In this work, we focus on the behavior of uranium and its surrogates, namely hafnium and neodymium, in aluminosilicate glasses from the Na2O-CaO-SiO2-Al2O3 system melted in highly reducing conditions. The first step consists in comparing the hafnium and uranium solubilities in the glass as functions of redox conditions and glass composition. A methodology has been set up and a specific device has been used to control the oxygen fugacity and the alkali content of the glass. The results show that uranium is far less soluble in the glass than hafnium (HfIV) in reducing conditions. The uranium solubility ranges from 4 to 7 wt% UO2 for an oxygen fugacity below 10-14 atm at 1250°C-1400°C. Uranium oxidation states have been investigated by X-ray absorption spectroscopy (XANES). It has been pointed out that UIV is the main form in the glass for such imposed oxygen fugacities. The second step of this work is to identify the glass-metal interaction mechanisms in order to determine the localization of uranium and its surrogates (Nd, Hf) in the glass-metal system. Mechanisms are mostly ruled by the presence of metallic aluminum and are similar for uranium, neodymium and hafnium. Glass-metal interaction kinetics demonstrate that uranium and its surrogates can temporarily be reduced into the metallic form for particular conditions. A re-oxidation occurs with time which is in good agreement with thermodynamics. Regarding uranium, the re-oxidation process must be corroborated. Finally, the formation and dissolution processes of the different crystalline phases observed during these glass-metal interactions have been studied using a thermodynamic approach based on phase diagrams

Verre aluminosilicaté

Uranium

Solubilité

Redox

Interactions verre-Métal

Xanes

Aluminosilicate glass

Uranium

Solubility

Redox

Glass-Metal interactions

Xanes

666.1

688.8

Síntesis de zeolitas mediante agentes directores de estructura usando procesamiento de datos masivos (Big Data)

León Rubio, Santiago

06 November 2023

Tesis por compendio / [ES] Las zeolitas son un material de aluminiosilicatos cristalinos microporosos extensivamente utilizados como catalizadores y tamices moleculares involucrados en procesos de separación. La mayoría de estos materiales son sintéticos, obtenidos en laboratorio mediante un proceso hidrotermal y barajando gran cantidad de variables como: relación sílice/agua, temperatura, tiempo, agitación y composición química. Cuando en la síntesis se introducen ciertas moléculas orgánicas, llamadas agentes directores de estructura, es más fácil entender y seleccionar moléculas específicas para dirigir la síntesis hacia una zeolita en particular. La situación ideal sería que cada agente director de estructura condujese la síntesis a una única zeolita, lo cual es poco probable que suceda, ya que, otros términos energéticos también juegan un papel importante, en particular el flúor y el aluminio. En esta tesis doctoral será acometido el estudio de estos tres factores: agente director de estructura, flúor y aluminio, además de su papel en la síntesis de zeolitas desde un enfoque químico-computacional. Proponiendo agentes directores de estructura más precisos para la síntesis de zeolitas, siendo sintetizadas de manera alternativa y/o más sostenible. / [CA] Les zeolites són un material d'aluminosilicats cristal·lins microporosos extensivament utilitzats com a catalitzadors i tamisos moleculars involucrats en processos de separació. La majoria d'aquests materials són sintètics, obtinguts en laboratori mitjançant un procés hidrotermal el qual presenta una gran quantitat de variables com: relació silici/aigua, temperatura, temps; agitació i composició química. Quan a la síntesi s'introdueixen unes certes molècules orgàniques, anomenades agents directors d'estructura, és més fàcil entendre i seleccionar molècules específiques per dirigir la síntesi cap a una zeolita en particular. La situació ideal seria que cada agent director d'estructura conduïra la síntesi a una única zeolita, la qual cosa és poc probable que succeïsca, ja que, altres termes energètics també juguen un paper important, en particular el fluor i l'alumini. En aquesta tesi doctoral es portarà a terme l'estudi d'aquests tres factors: agent director d'estructura, fluor i alumini, a més del seu paper en la síntesi de zeolites des d'un enfocament químic-computacional. Proposant agents directors d'estructura més precisos per a la síntesi de zeolites, sent sintetitzades de manera alternativa i/o més sostenible. / [EN] Zeolites are a microporous crystalline aluminosilicate material extensively used as catalysts and molecular sieves involved in separation processes. Most of these materials are synthetic, obtained in the laboratory by means of a hydrothermal process, and by shuffling a large number of variables such as silica/water ratio, temperature, time, agitation, and chemical composition. When certain organic molecules, called structure-directing agents, are introduced in the synthesis, it is easier to understand and select specific molecules to direct the synthesis towards a particular zeolite. The ideal situation would be for each structure-directing agent to drive the synthesis to a single zeolite, which is unlikely to happen, since, other energetic terms also play an important role, in particular fluorine and aluminum. In this doctoral thesis, the study of these three factors: structure directing agent, fluorine, and aluminum, and their role in zeolite synthesis will be undertaken from a chemical-computational approach. Proposing more precise structure-directing agents for the synthesis of zeolites, being synthesized in an alternative and/or more sustainable way. / León Rubio, S. (2023). Síntesis de zeolitas mediante agentes directores de estructura usando procesamiento de datos masivos (Big Data) [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/199280 / Compendio

Zeolitas

Sílice

Aniones

Aluminosilicato

Estabilidad

Bases de datos biológicas

Cavidades

Moléculas

Aluminosilicate

Anions

Energy

Silica

Zeolites

Stability

Biological databases

Cavities

Molecules

Espectroscopia linear e não linear em vidros aluminosilicato de cálcio dopados com Térbio / Linear and nonlinear spectroscopy in Terbium doped calcium aluminosilicate glasses

Santos, Jéssica Fabiana Mariano dos

09 May 2019

Apresentamos uma série de novos resultados acerca dos vidros aluminosilicato de cálcio com diferentes concentrações de sílica (7,0 e 34,0% em massa) dopados com o íon Tb3+ (Tb4O7 = 0,05 - 15,0% em massa). A partir de medidas de absorção, excitação, emissão e tempos de decaimento; discutimos detalhadamente os mecanismos de emissão verde e azul do Tb3+ neste sistema vítreo. As emissões na região do azul (nível 5D3) foram analisadas tanto pela excitação direta no UV (emissão de Stokes) quanto por conversão ascendente de energia (emissão anti-Stokes), após a excitação em 488 nm (excitação ressonante com o nível 5D4). Para excitação em 325 nm, verificou-se que a intensidade da luminescência verde aumenta linearmente com a concentração, enquanto a emissão azul é fortemente reduzida com o aumento da concentração de Tb3+. No caso da excitação em 488 nm, observou-se uma forte saturação das emissões no verde, para intensidades duas ordens de grandeza menores que o esperado (Isat = 2,3×106 W/cm2). Por meio de um sistema de equações de taxa, mostramos que esse comportamento pode ser explicado pelo mecanismo de absorção do estado excitado e por uma seção de choque de absorção (5D4 → 5D3) aproximadamente duas ordens de magnitude maior do que a observada na transição 7F6 → 5D4. Espectros de excitação e emissão realizados a baixa temperatura (6 K) evidenciaram a presença de emissões atribuídas à matriz hospedeira. Medidas de Z-scan resolvidas no tempo, com excitação em 488 nm também foram realizadas e nos permitiram calcular a variação da polarizabilidade (Δαp) das amostras. A concentração de sílica apresentou forte influência nas propriedades não lineares aferidas. Para a amostra com menor concentração de sílica (7,0% em massa), o valor de Δαp é aproximadamente 10 vezes maior do que para a amostra com maior concentração de sílica (34% em massa). / We present a series of new results concerning Tb+3 (Tb4O7 = 0,05 - 15,0 wt.%) doped calcium aluminosilicate glasses with different silica concentrations (7.0 and 34.0 wt.%). Through optical absorption, excitation spectra, photoluminescence, and fluorescence decay measurements, the blue and green Tb+3 emission are discussed in detail. Emissions in the UV-blue region (5D3 level) were analyzed by direct UV excitation (Stokes emission) and by upconversion (anti-Stokes emission), resonant excitation with level 5D4 level. For the excitation at 325 nm, the intensity of the green luminescence increases linearly with the Tb+3 concentration. In opposite, the blue emission is strongly reduced with increasing the Tb+3 concentration from 0.5 to 15.0% (wt%). In the case of the 488 nm excitation, strong saturation of the green emissions was observed for pump intensity two orders of magnitude lower than expected (Isat = 2,3×106 W/cm2). By means a rate equations system, we explain this behavior by the excited state absorption and by an absorption cross section (5D4 → 5D3) approximately two orders of magnitude larger than 7F6 → 5D4 transition. Excitation and emission spectra were performed at low temperature (6 K) in the Tb doped LSCAS glass. These spectra showed matrix emission bands. Time-resolved Z-scan measurements were performed (at 488 nm). From these measurements, we determine the polarizability change (Δαp) in Tb doped glasses. The silica concentration presents a great influence on the nonlinear properties measured. The Δαp value in low silica calcium aluminosilicate glass (7.0 wt.%) is approximately 10 times higher than the value determined the sample with a higher silica content (34.0 wt.%).

Calcium aluminosilicate glass

Energy transfer processes

Espectroscopia

Íon Térbio trivalente

Processos de transferência de energia

Spectroscopy

Técnica de Z-scan

Trivalent terbium ions

Vidros aluminosilicato de cálcio

Z-scan technique