Preparação e caracterização microestrutural e dielétrica da perovsquita CaCu3Ti4O12 / Preparation, microstructure and dielectric characterization of the CaCu3Ti4O12 perovskite

Tatiane Cristina Porfirio

25 August 2015

Neste trabalho pós de CaCu3Ti4O12 foram preparados por reação em estado sólido e por técnicas de solução: complexação de cátions e coprecipitação dos oxalatos. Foram realizados estudos de formação de fase, densificação e propriedades dielétricas das cerâmicas sinterizadas. Para efeito comparativo, ta is propriedades foram determinadas em amostras puras e contendo dissilicato de lítio (LSO) e fluoreto de lítio (LiF) como aditivos de sinterização. O principal objetivo foi verificar o efeito do uso dos diferentes aditivos de sinterização na microestrutura, densificação e propriedades dielétricas do CCTO. Os principais resultados revelaram que pós preparados por técnicas de solução apresentam fase única após calcinação em condições selecionadas. Foi verificado que os aditivos influenciam na densificação, possibilitando obter cerâmicas com 95% da densidade teórica do CCTO a 1025°C. As amostras preparadas por diferentes técnicas apresentam propriedades similares, com exceção das características microestruturais. A permissividade elétrica determinada à temperatura ambiente é da ordem de 104 independentemente do método de síntese. As menores perdas dielétricas foram obtidas para amostras contendo LiF como aditivo de sinterização. / In this work the effects of the method of synthesis and sintering additives on the microstructure and dielectric properties of CCTO were investigated. Powder mixtures were prepared by the cation complexation and coprecipitation methods, and by mixing of the starting oxides, for comparison purposes. Lithium dissilicate (LSO) and lithium fluoride (LiF) were used as sintering aids. The main results revealed that powders prepared by solution techniques have single phase after calcination at selected conditions. The additives were found to influence the densification allowing for obtaining high relative density (≥ 95%) at 1025ºC. Specimens prepared by different methods show similar properties except on microstructure features. The electric permittivity is of the order of 104 for all investigated specimens independent on the method of synthesis. The dielectric loss is found to be lower for specimens prepared with LiF as sintering aid.

aditivos

CCTO

permissividade elétrica

síntese química, perdas dielétricas

additives

CCTO

chemical synthesis

dielectric loss

electric permittivity

Síntese e caracterização de hidróxidos de alumínio com duas dimensões nanométricas (morfologia fibrilar) ou com uma dimensão nanométrica (morfologia de placas/lâminas). / Synthesis and characterization of aluminum hydroxides with two nanometric dimensions (fibrillar morphology) or one nanometric dimension (morphology boards / blades).

Gisele de Araujo Rocha

27 May 2013

A síntese de nanopartículas com morfologia controlada vem sendo objeto de interesse crescente no campo da Ciência dos Materiais. Devido a essa motivação, o principal objetivo desse trabalho foi a síntese e caracterização de pseudoboemita e boemita apresentando uma ou duas dimensões nanométricas. O método de síntese utilizado para a obtenção de pseudoboemita fibrilar é baseado na reação de um alcóxido de alumínio, em solução aquosa de ácido acético. Para a preparação de boemita, um único método de síntese, a síntese hidrotérmica, foi utilizado, com o emprego de três precursores: uma pseudoboemita, um sal orgânico (o monohidróxido diacetato de alumínio) e o trihidróxido de alumínio gibsita, este último em duas formas: uma gibsita comercial e uma gibsita sintetizada que utiliza iodo como ativador. As pseudoboemitas e as boemitas obtidas foram caracterizadas por difração de raios-X e microscopia eletrônica de varredura. Algumas amostras de pseudoboemita e de boemita foram caracterizadas por análise térmica diferencial e por espectroscopia vibracional na região do infravermelho. Foram obtidas pseudoboemitas com morfologia fibrilar (partículas anisométricas alongadas); no caso das boemitas foram produzidas distintas morfologias (de acordo com o precursor e com as condições de síntese empregadas em sua obtenção): fibrilar (duas dimensões em escala nanométrica), nanoplacas (uma dimensão em escala nanométrica) e partículas com simetria cúbica (nenhuma dimensão em escala nanométrica). A presença do íon acetato na síntese hidrotérmica foi determinante na formação de boemita com morfologia de placas. / The synthesis of nanoparticles with controlled morphology is of increasing interests in the field of Materials Science. Due to this motivation, the main objective was the synthesis and characterization of boehmite pseudoboehmite presenting one or two nanoscale dimensions. The method of synthesis used to obtain fibrillar pseudoboehmite is based on the reaction of an aluminum alkoxide in aqueous acetic acid. For the preparation of boehmite, a single synthesis method, the hydrothermal synthesis, was used with three different precursors: a pseudoboehmite, an organic salt (aluminum monohydroxide diacetate) and the aluminum trihydroxide gibbsite, the latter in two forms: a commercial gibbsite and a gibbsite synthesized that utilizes iodine as activator. The pseudoboehmites and boehmites obtained were characterized by X-ray diffraction and scanning electron microscopy. Some samples of pseudoboehmite and boehmite were characterized by differential thermal analysis and by vibrational spectroscopy in the infrared region. Pseudoboehmites were obtained with fibrillar morphology (anisometric elongated particles); for boehmites, different morphologies were produced (according to the precursor and the synthesis conditions employed in their production): fibrillar (two dimensions in nanoscale), nanoplates (one dimension in nanoscale) and particles with cubic symmetry (no dimensions in nanoscale). The presence of acetate ion in hydrothermal synthesis was instrumental in the formation of boehmite with plate morphology.

Alumínio

Nanotecnologia

Síntese química

Aluminum

Aluminum hydroxide

Boehmite

Chemical synthesis

Hydrothermal synthesis

Nanotechnology

Assemblage dirigé de nanocristaux métalliques / Directed assembly of metallic nanocrystals

Kameche, Farid

25 September 2015

Le contrôle de l'organisation bidimensionnel de nanoparticules est primordial dans le défi que représentent l'enregistrement magnétique et l'augmentation de la capacité de stockage. Plus particulièrement, c'est ici la diminution de la taille des bits d'informations qui est ciblée. La conséquence serait alors une augmentation de la capacité de stockage de deux à trois ordres de grandeurs. Mais pour ce faire, il est nécessaire d'avoir une organisation bidimensionnelle de nanoparticules magnétiques de taille, forme et composition contrôlée. Via deux méthodes de synthèse, des nanoalliages de CoPt et Co33Pt67 de l'ordre de 2 nm ont été synthétisées. Ces derniers ont présenté alors des températures de blocage et des champs coercitifs ne permettant pas leurs utilisations dans des applications dans l'enregistrement magnétique. Cela s'explique par le fait qu'après synthèse, ces nanoparticules sont désordonnées chimiquement. Afin d'améliorer l'ordre chimique et donc les propriétés magnétiques, des recuits thermiques ont été effectués. Il a été montré que la mise en ordre a lieu vers 400°C et que, dans le cas de nanocristaux de Co33Pt67, la forme et la taille restent inchangées. Ces derniers pourraient être utilisés dans l'enregistrement magnétique à condition de pouvoir contrôler la distance interparticulaire. C'est pourquoi nous avons utilisé des molécules organiques capables de s'auto-assembler sur surface sur de longues distances et formant des réseaux nanoporeux aptes à servir de systèmes hôte et à capter les nanoparticules. Nous avons alors montré que des nanoparticules de platine possèdent une organisation quasi-hexagonale et monoclinique à moyenne distance. / The fine control of nanoparticles bi-dimensional organization remains a main challenge for magnetic recording applications. Although the current size for a data bit is around a few tens of nanometers, it could be reduced to the nanometer scale simply through using magnetic nanoparticles. Nonetheless, intrinsic parameters of the nanoparticles such as their sizes, shapes and chemical compositions have a direct incidence on their periodic arrangement. Two different chemical routes were used to synthesize 2 nm CoPt and Co33Pt67 nanoalloys. Due to the high chemical disordering of these nanocrystals, the blocking temperature and coercive fields were lower than wished for data storage applications. In order to exhibit a higher chemical ordering, in situ annealing of these nanocrystals was carried out. It has been shown that ordering occurred around 400°C. Plus, size and shape for Co33Pt67 were kept after annealing but not for equiatomic composition. Nevertheless, only poor mesoscopic ordering between nanoparticles is observed, as reported elsewhere. This hurdle could be overcome in using organic molecules able to self-assemble on graphite and forming a porous two-dimensional supramolecular template. Thus, such template was designed and used to demonstrate that 2 nm Pt nanoparticles can locally organize in quasi-hexagonal or monoclinic lattices.

Synthèse chimique

Nanoparticules métalliques

CoPt

Mise en ordre

Assemblage dirigé

Tamis moléculaire

Nanoalliages

Nanoalloys

Chemical synthesis

541.3

Opatření pro zvýšení efektivity výzkumu v oboru chemické syntézy (Measures towards increasing the effectiveness of research in the field of chemical synthesis) / Measures towards Increasing the Effectiveness of Research in the Field of Chemical Synthesis

Václavík, Jiří

January 2015

Research in the field of chemical synthesis is a very diverse and complex activity. Individual workplaces differ in many aspects and this essentially impacts the productivity. The aim of this Master's Thesis is to identify, name and analyse those aspects, and to suggest measures to be taken in order to help increase the performance, all that within defined assumptions. The first half of the Theoretical Part is devoted to academic studies on this topic, which are mainly focused on the HR part. Selected methods of lean manufacturing commonly used in industry are also described. The Experimental Part comprises an analysis of research facilities in which the author worked as a chemist, and a set of proposed measures that lead to an increased productivity. The Thesis is concluded by a demarcation of a series of factors that influence the performance of R&D workers, groups and institutions, and a vision of an ideal laboratory is presented.

Sustainable, energy-efficient hydrogenation processes for selective chemical syntheses.

Yao, Libo

29 July 2021

No description available.

Chemical Engineering

Catalytic Reductive Carbene and Vinylidene Transfer Reactions

Conner M Farley (8763057)

29 April 2020

<div>Carbenes are reactive organic intermediates comprised of a neutral, divalent carbon atom. The reactivity of carbenes is often orthogonal to polar functional groups (nucleophiles and electrophiles), making them valuable intermediates for organic synthesis. For example, carbenes can engage in cheletropic reactions with olefins to form cyclopropane rings or undergo insertions into weak element-hydrogen bonds. The most established strategy for accessing carbene intermediates is through a redox-neutral decomposition of diazoalkanes to form a transient M=CR₂ species. Over the course of nearly a half-century of development, many instrumental synthetic methods have emerged that operate on this basis. Despite the combined utility of these methods, the scope of catalytic carbene transfer reactions remains largely constrained by the inherent instability of the starting materials. Diazoalkanes often require electron-withdrawing groups to provide stability through resonance effects.</div><div>Contrary to redox-neutral methods, reductive carbene transfer reactions utilize non-stabilized 1,1-dihaloalkanes as carbene precursors. The Simmons-Smith cyclopropanation reaction represents the most documented example of this class, and remains today as the most practical method for parent methylene (:CH₂) transfer. Nevertheless, reductive carbene transfer processes have proven to be remarkably resistant to catalysis. Our group is interested in developing first-row transition metal catalysts which can initiate an oxidative addition into 1,1-dihaloalkanes, followed by a two-electron reduction with an outer-sphere reductant to provide access to a M=CR₂ intermediate for carbene transfer.</div><div>The application of this mechanistic hypothesis toward reductive methylene transfer using CH₂Cl₂ as the carbene source and a Ni catalyst is outlined in chapter one. The discovery of an unexpected cyclooligomerization of methylene carbenes is discussed. Mechanistic studies are presented, which are consistent with a pathway in which carbenes are iteratively inserted into an expanding metallacycle. In chapter two, the corresponding activation of 1,1-dichloroalkenes for vinylidene transfer in [5+1]-cycloadditions with vinylcyclopropanes is outlined. Finally, in the third and final chapter, organic reactions catalyzed by complexes which feature metal-metal bonds are reviewed.</div>

Organic Chemistry

Organic Chemical Synthesis

Catalysis and Mechanisms of Reactions

Carbene

Nickel

Catalysis

Cobalt

Vinylidene

Cycloaddition

Ruthenium Compounds for Photodynamic Chemotherapeutics and Solar Fuel Generation

Delsorbo, Carter A, McCullough, Annie B, Peiro'Vila, Pau, Pulliam, Lyndsey B, Rojas, Alyssa N, Sager, Kayla M, Ashford, Dennis L

12 April 2019

Ruthenium polypyridyl complexes have long been studied due to their unique photophysical characteristics and their synthetic accessibility. We report here the use of new ruthenium polypyridyl’s in photodynamic chemotherapeutic and solar fuel applications. Nearly half of all chemotherapeutics administered today are derived from platinum-based drugs (platins) which lack specificity and can cause sever side-effects. Photodynamic chemotherapeutics (PDT) circumvent these issues utilizing light activation at the site of cancerous cells to generate a cytotoxic Ru(II) center and eventually trigger cellular apoptosis. The new PDT pro-drugs presented push their metal-to-ligand charge transfer (MLCT) light absorption out into the near-IR which is able to penetrate skin at greater depths than traditional PDT drugs. New Ru(II) hydrogen fuel evolution catalyst for use in dye-sensitized photoelectrosynthesis cells (DSPECs) based off of the extensively explored octahedral tridentate-bidentate coordination motif is also investigated. In particular, pendant bases are oriented toward the active site of the catalyst to increase catalytic rates and lower overpotentials. Preliminary density functional theory calculations show that strategic placement of the pendant amine on the bidentate ligand allows for productive interactions between the base and the active site of the catalyst to evolve hydrogen.

ruthenium

chemotherapy

solar energy

Chemical Synthesis

Electrochemistry

Heterocyclic Chemistry

Inorganic Chemistry

Ligands

Organic Chemistry

HIGH-THROUGHPUT EXPERIMENTATION OF THE BUCHWALD-HARTWIG AMINATION FOR REACTION SCOUTING AND GUIDED SYNTHESIS

Damien Edward Dobson (12790118)

16 June 2022

<p>  </p> <p>Aromatic C-N bond formation is critical for synthetic chemistry in pharmaceutical, agrochemical, and natural product synthesis. Due to the prevalence of this bond class, many synthetic routes have been developed over time to meet the demand. The most recent and robust C-N bond formation reaction is the palladium catalyzed Buchwald-Hartwig amination. Considering the importance of the Buchwald-Hartwig amination, a high-throughput experimentation (HTE) campaign was devised to create a library in which chemists can refer to optimal reaction conditions and ligand/catalyst choice based on the nature of their substrates to be coupled. This study showed trends for the appropriate choice of ligand and catalyst, along with what bases, temperatures, stoichiometries, and solvents are appropriate for the selected substrate combination at hand. </p>

Organic chemical synthesis

high throughput experimentation

Organic Syntheses

Buchwald Hartwig amination

palladium-based

SYNTHETIC STUDIES TOWARDS THE HAMIGERANS WITH A [6–7–5] TRICYCLIC SKELETON

Baiyang Jiang (12422548)

15 April 2022

<p>The hamigeran diterpenoid is a family of natural products with diverse structures and biological activities. Most of the syntheses focus on hamigerans with [6–6–5] tricyclic core, but synthetic efforts toward the more challenging [6–7–5] tricyclic hamigerans are very limited. Herein, our studies in synthesizing the [6–7–5] tricyclic hamigerans are disclosed.  Through a benzyne-β-ketoester annulative ring expansion and a Nazarov reaction, an approach toward the [6–7–5] tricyclic carbon skeleton of the hamigeran natural products was developed. A Ni-catalyzed conjugate methyl addition or a Corey–Chaykovsky reaction installed the all-carbon quaternary center, and a Suzuki cross coupling followed by reduction introduced the isopropyl group. However, the reduction of challenging tetra-substituted double bond or the regio-selective cyclopropane opening was not successful despite multiple conditions were tried. A revised synthetic strategy was proposed and resulted in a convergent total synthesis of (±)-hamigeran M, enabled by five C–H functionalization reactions and proceeding in 11 steps in 3.9% overall yield. The C–H functionalizations include a hydroxy-directed C–H borylation, one C–H metalation-1,2-addition, one C–H metalation-Negishi coupling, a late-stage oxazole-directed C–H borylation-oxidation, and one electrophilic bromination. Further elaboration of the intermediates obtained here has delivered an advanced polysubstrituted precursor towards multiple other hamigerans.</p>

Organic Chemistry

Natural Products Chemistry

Organic Chemical Synthesis

Hamigeran

Total Synthesis

PROCESS DEVELOPMENT FOR THE SYNTHESES OF ESSENTIAL MEDICINES IN CONTINUOUS FLOW

Robert John Nicholas (12456744)

25 April 2022

<p>A significant number of resources are allocated to maintaining the resiliency of pharmaceutical supply chain as failure to do so thoroughly can result in drug shortages of essential medicines. Recently, the effects of COVID-19 exacerbated flaws in the current system causing the pharmaceutical industry and government organizations and to reassess relief strategies that could also strengthen the supply chain. Flow chemistry has become an attractive and prominent platform enabling continuous manufacturing (CM) technologies to synthesize active pharmaceutical ingredients (API) quickly according to demand. Compared to traditional batch chemistry, flow chemistry has demonstrated to be more robust in terms of throughput, scalability, and hazard reduction while maintaining a high degree of control and product quality. This work demonstrates these capabilities in reaction optimization and discovery with the overarching goal of domesticating CM to make essential medicines more affordable. A two-step process for the synthesis in diazepam was developed using a Chemtrix Labtrix S1 and Start microfluidic systems where purities as high as 98% were achieved. The system was successfully scaled up to a larger system that was able to produce 96% pure diazepam at a 91% yield. </p>

Organic Chemistry

Organic Chemical Synthesis

Industrial Chemistry

Pharmaceuticals

Flow Chemistry

Process Optimization

Diazepam

Supply Chains