Laponite-supported titania photocatalysts

Daniel, Lisa Maree

January 2007

This thesis describes the synthesis and characterisation of titania photocatalysts for incorporation into a polyethylene film. Monodisperse, anatase-phase titania nanoparticles are prepared and the synthesis conditions necessary for attraction to a laponite clay support are determined. Methods of preventing agglomeration of the laponite system such as the use of a polyethylene oxide surfactant or chemical modification of the laponite plate edges with a dimethyloctyl methoxysilane are also explored. Finally, photocatalytic studies on the laponite-supported titania nanoparticles are performed, and the compatibility and photoactivity of these materials in the polyethylene film are examined.

Titania

titanium dioxide

anatase

photoactivity

photocatalyst

clay

colloid

hydrothermal treatment

laponite

surfactant

silane

silylation

edge-modification

X-ray diffraction

polymer degradation

transmission electron microscopy

infrared emission spectroscopy

BET N2 sorption

thermogravimetric analysis

Exploring Diverse Facets of Small Molecules by NMR Spectroscopy

Chaudhari, Sachin Rama

January 2014

The thesis entitled “Exploring Diverse Facets of Small Molecules by NMR Spectroscopy” consists of six chapters. The main theme of the thesis is to exploit one and two dimensional NMR methodologies for understanding the diverse facets of small organic molecules, such as, weak intra- and inter- molecular interactions, chiral discrimination, quantification of enantiomeric excess and assignment of absolute configuration. Several new pulse sequences have also been designed to solve specific chemical problems, in addition to extensive utility of existing one and two dimensional NMR experiments. The results obtained on different problems, are discussed under six chapters in the thesis. The brief summary of each of these chapters is given below. Chapter 1 begins with the discussion on the importance of small molecules and their various facets, the analytical techniques available in the literature to study them. The role of NMR spectroscopy as powerful analytical technique to understand the diverse facets of organic molecules and their importance is set out in brief. A short introduction to the basic principles of NMR, the interaction parameters, the commonly employed one and two dimensional homo- and herero- nuclear NMR experiments are also given. The basic introduction to product operators essential for understanding the spin dynamics in the developed pulse sequences is given. The application of diffusion ordered spectroscopy (DOSY), the general problems encountered in the analysis of combinatorial mixtures and the matrix assisted method in circumventing such problems are discussed. Chapter 2 focuses on the chiral discrimination and the measurement of enatiomeric excess. The NMR approach to discriminate enantiomers using chiral auxiliaries such as, solvating agents, derivatizing agents, lanthanide shift reagents, the choice of such auxiliaries and the limitations are discussed in detail. The in-depth discussion on the new protocols developed using both the solvating and derivatizing agents for enantiomeric discrimination of chiral amines, hydroxy acids and diacids are discussed. The new three-component protocols that serve as chiral derivatizing agents for the discrimination of primary amines, diacids and hydroxy acids are discussed. Also the role of organic base such as DMAP in the chiral discrimination is explored for discrimination of acids using BINOL as a chiral solvating agent. Accordingly the discussion is classified into two sections. In the first section the protocol developed utilizing an enantiopure mandelic acid, a primary amine substrate and 2-formylphenylboronic acid that is ideally suited for testing the enantiopurity of chiral primary amines is discussed. The broad applicability of the protocols for testing enantiopurity has been demonstrated on number of chiral molecules using 1H and 19F NMR. The second section contains the results on the new concept developed for discrimination of hydroxy acids. The strategy involves the formation of three component protocol using chiral hydroxy acid, R-alphamethylbenzylamine and 2-formylphenylboronic acid for 1H-NMR discrimination of diacids. The section also includes the utility of ternary ion-pair complex for the discrimination of acids. The ternary ion-pair not only permitted the testing of enantiopurity of chiral acids, but is also found useful for the measurement of enantiomeric excess. Chapter 3 discusses the utilization of the developed three-component protocols for the assignment of absolute configurations of molecules of different functionality. The protocols for the assignments of absolute configuration of primary amines using 2-formylphenylboronic acid and mandelic acid yielded the substantial chemical shift differences between diastereomers. The consistent trend in the direction of change of chemical shifts of the discriminated proton(s) gave significant evidence for employing them as parameters for the assignment of spatial configuration of primary amines. Another protocol using 2-formylphenylboronic acid, hydroxy acids and enantiopure alphamethylbenzylamine permitted their configurational assignment. In the second section a novel solvating agent, obtained by the formation of an ion-pair complex among enantiopure BINOL, DMAP and chiral hydroxy acid for the assignment of the spatial configuration of hydroxy acids is discussed. Chapter 4 focuses on the development of novel NMR methodologies, and also the utility of existing two-dimensional experiments for addressing certain challenging problems. This chapter has been divided into three sections. In Section-I the utilization of well-known homonuclear 2D-J-resolved methodology for unravelling the overlapped NMR spectra of enantiomers, an application for chiral discrimination and the measurement of enantiomeric excess is discussed. The utilization of the chiral auxiliaries, such as, chiral derivatizing agents, chiral solvating agents and lanthanide shift reagents permits enantiodiscrimination and the measurement of excess of one form over the other. Nevertheless many a times one encounters severe problems due to small chemical shift difference, overlap of resonances, complex multiplicity pattern because of the presence of number of interacting spins, and enormous line broadening due to paramagnetic nature of the metal complex. This section is focused on combating such problems utilizing 2D-J-1JNH resolved spectroscopy where a 450 tilting of the spectrum in the F2 dimension, yielded the pure shift NMR spectrum. The method circumvents several problems involved in chiral discrimination and allows the accurate measurement of enantiomeric excess. In Section-II, the development of novel NMR experimental methodology cited in the literature as C-HetSERF and its application for the study of symmetric molecules, such as, double bonded cis- and trans- isomers, and extraction of magnitudes and signs of long range homo- and hetero- nuclear scalar couplings among chemically equivalent protons in polycylic aromatic hydrocarbons is discussed. The extensive utility of the new pulse sequence has been demonstrated on number of symmetric molecules, where the conventional one dimensional experiment fails to yield spectral parameters. In section III, yet another novel pulse sequence called RES-TOCSY developed for unravelling of the overlapped NMR spectrum of enantiomers and the measurement of enantiomeric contents, has been utilized for the accurate measurement of magnitudes and signs of 1H-19F couplings in fluorine containing molecules. The method has distinct advantages as the strengths of the couplings and their relative signs could be extracted on diverse situations, such as, couplings smaller than line widths, the spectrum where the coupling fine structures are absent. Chapter 5 covers the study of nature of intra- and inter- molecular hydrogen bond in amide and its derivative. The chapter is accordingly divided into two sections. In the first section the study of acid and amide hydrogen bonding is discussed and the hydrogen bonded interactions are probed by extensive utility of 1H, 13C and 15N-NMR. The temperature perturbation experiments, measurements of the variation in the couplings, monitoring of diffusion coefficients and the association constants, detection of through space correlation have given unambiguous evidence for the hydrogen bond formation. The results were also supported by DFT calculations. Similar interaction in the solid state has also been derived by obtaining the crystal structure of complex phenylacetic acid with benzamide. In the second section of the chapter the hydrogen bond interaction of organic fluorine in trifluoromethyl derivatives of benzanilides has been explored and the involvement of CF3 group in the hydrogen bonding has been detected. The evidence for the participation of CF3 group in hydrogen bond has been confirmed by number of experiments, such as, the detection of through space couplings, viz., 1hJFH, 1hJFN, and 2hJFF , where the spin polarization between the interacting spins is transmitted through hydrogen bond, the temperature and solvent dependent studies, variation in the 1JNH and two dimensional heteronuclear correlation experiments. In an interesting example of a molecule containing two CF3 groups situated on two phenyl rings of benzanilide, the simultaneous participation of fluorines of two CF3 groups in hydrogen bond has been detected. The confirmatory evidence for such an interaction, where hydrogen bond mediated couplings are not reflected in the NMR spectrum, has been derived by 19F−19F NOESY. Significant deviations in the strengths of 1JNH, in addition to variable temperature, and the solvent induced perturbation studies yielded additional evidence. The NMR results are corroborated by both DFT calculations and MD simulations, where the quantitative information on different ways of involvement of fluorine in two and three centered hydrogen bonds, their percentage of occurrences, and geometries have been obtained. The hydrogen bond interaction energies have also been calculated. The study revealed the rare observation and the first example of the C-F…H-N hydrogen bond in solution state in the molecules containing CF3 groups. Chapter 6 focuses on the mixture analysis using the diffusion ordered spectroscopy (DOSY). High Resolution-DOSY works when the NMR spectrum is well resolved and the diffusion coefficients of the combinatorial mixtures are substantially different from each other. DOSY technique fails when the mixture contains the molecules of nearly identical weights and similar hydrodynamic radii. Thus, the positional isomers, enantiomers consequent to their nearly identical rates of diffusion, are not differentiated. Some of these problems can be overcome by Matrix-Assisted Diffusion Order Spectroscopy (MAD-spectroscopy), where an external reagent acts as a matrix and aids in their diffusion edited separation, provided the molecules embedded in it possess differential binding abilities with the matrix. Such different binding properties of the matrix are the basis for resolution of many isomeric species. In the present study three different novel auxiliaries, micelles-reverse micelles, crown ether and cyclodextrin are introduced for the resolution of positional isomers, double bonded isomers, viz., fumaric acid and maleic acid and also enantiomers. Accordingly, the results of each of these studies are discussed in three different sections.

Nuclear Magnetic Resonance Spectroscopy

Molecular Spectroscopy

Nuclear Magnetic Resonance

Chiral Discrimination

Chirality (Chemistry)

Hydrogen Bonding

Acid-Amide Hydrogen Bonding

Small Organic Molecules

Diffusion Ordered Spectroscopy

1H NMR

Chiral Carboxylic Acid

NMR Spectroscopy

NMR Spectrum

Analytical Chemistry

Poliuretanas: caracterização, avaliação estrutural e efeito induzido pela radiação gama / Polyurethanes: characterization, structural evaluation and effect induced by gamma radiation

Lage, Laércio Gomes

26 August 2003

Poliuretana (PUR) é uma classe de polímeros que possui grupos uretânicos [-O-C(=O)-NH-] em sua estrutura e encontra diversas aplicações, inclusive na área biomédica. Esta versatilidade é devida ao uso de diferentes monômeros em sua síntese. O uso de isocianatos cicloalifáticos, um dos monômeros da PUR, é mais vantajoso em aplicações que requeiram uma maior estabilidade térmica e à radiação ultravioleta e maior resistência à hidrólise. Quando processadas inapropriadamente, as PUR baseadas em isocianatos aromáticos produzem compostos carcinogênicos, fato não observado para as PUR com isocianatos cicloalifáticos. Visando a aplicação biomédica, a PUR tem sido modificada através da incorporação de grupos iônicos à cadeia polimérica, formando ionômeros. A esterilização de materiais de uso biomédico é feita pelo emprego de óxido de etileno ou da radiação gama. Neste trabalho, visou-se a síntese e caracterização da PUR e do ionômero sultanado desta, baseadas em isocianato cicloalifático, além do estudo do efeito da radiação gama nos polímeros. Foi observado através da espectroscopia vibracional e análise elementar que se formam ligações de alofanato, uma ramificação da PUR linear. Comparando-se a PUR sintetizada com uma amostra comercial de PUR linear de uso biomédico, amorfa, verificou-se que a primeira apresentava cristalinidade. O estudo da cinética de decomposição térmica da PUR permitiu estabelecer o mecanismo com o qual acontece a decomposição. A estabilidade térmica e cristalinidade da PUR sulfonada são maiores que para a PUR, devendo estar relacionadas à contribuição dos grupos sulfonato. A PUR sulfonada tem um maior tempo de vida estimado que a PUR, nas temperaturas estudadas. A irradiação das amostras permitiu a verificação da oxidação do segmento do poliol e/ou extensor de cadeia, por meio da diminuição de intensidade das bandas relacionadas a este segmento nos espectros vibracionais e diminuição da cristalinidade por DSC. / Polyurethane (PUR) is a class of polymers that possesses urethane groups [O-C(=O)-NH-] in its structure and that find many applications, including biomedical ones. This variety is due to the use of different monomers in its synthesis. The use of aliphatic isocyanates, one of PUR monomers, is more valuable in applications that demand stability to UV radiation, resistance to hydrolysis, and a greater thermal stability. The aromatic isocyanate-based PUR produces, when processed incorrectly, carcinogenic compounds, a fact that is not observed in the cycloaliphatic isocyanate-based PUR. The PUR modification to use it in biomedical artifacts has been made, among some procedures, through the incorporation of ionic groups into the polymer chain, forming ionomers. The biomedical materials sterilization is made employing ethylene oxide or gamma radiation. The objectives of this work are the synthesis and characterization of PUR and its sulfonated ionomer, both based on a cycloaliphatic isocyanate, as well as the study of the effect of gamma radiation in the polymers. It has been observed the formation of allophanate linkages through the analysis of vibrational spectra and elemental analysis data. Comparing the synthesized PUR and a commercial, amorphous, linear PUR used in biomedical artifacts, it has been noted that the former has crystallinity. The kinetic study of thermal decomposition of PUR allowed to establish the decomposition mechanism of PUR. The thermal stability and crystallinity of sulfonated PUR are greater than of PUR, probably due to the contribution of sulfonic groups. The lifetime of sulfonated PUR is greater than that of PUR, in the temperature range studied. The samples irradiation has permitted the observation of poliol and/or chain extender oxidation, by means of the decreasing of the intensity of the vibrational bands related to these groups and the decreasing of crystallinity in DSC.

Analysis

DSC

DSC

Espectroscopia Raman

Evaluation)

Físico-química orgânica

Gamma radiation

Infrared photoacoustic spectroscopy

Infrared spectroscopy (Applications

Organic physicochemistry

Physico-chemical analysis)

Poliuretana

Polymers (Materials) (Characteristics

Polyurethane

Radiação gama

Raman spectroscopy

Structure

Study

TG

TG

Poliuretanas: caracterização, avaliação estrutural e efeito induzido pela radiação gama / Polyurethanes: characterization, structural evaluation and effect induced by gamma radiation

Laércio Gomes Lage

26 August 2003

Poliuretana (PUR) é uma classe de polímeros que possui grupos uretânicos [-O-C(=O)-NH-] em sua estrutura e encontra diversas aplicações, inclusive na área biomédica. Esta versatilidade é devida ao uso de diferentes monômeros em sua síntese. O uso de isocianatos cicloalifáticos, um dos monômeros da PUR, é mais vantajoso em aplicações que requeiram uma maior estabilidade térmica e à radiação ultravioleta e maior resistência à hidrólise. Quando processadas inapropriadamente, as PUR baseadas em isocianatos aromáticos produzem compostos carcinogênicos, fato não observado para as PUR com isocianatos cicloalifáticos. Visando a aplicação biomédica, a PUR tem sido modificada através da incorporação de grupos iônicos à cadeia polimérica, formando ionômeros. A esterilização de materiais de uso biomédico é feita pelo emprego de óxido de etileno ou da radiação gama. Neste trabalho, visou-se a síntese e caracterização da PUR e do ionômero sultanado desta, baseadas em isocianato cicloalifático, além do estudo do efeito da radiação gama nos polímeros. Foi observado através da espectroscopia vibracional e análise elementar que se formam ligações de alofanato, uma ramificação da PUR linear. Comparando-se a PUR sintetizada com uma amostra comercial de PUR linear de uso biomédico, amorfa, verificou-se que a primeira apresentava cristalinidade. O estudo da cinética de decomposição térmica da PUR permitiu estabelecer o mecanismo com o qual acontece a decomposição. A estabilidade térmica e cristalinidade da PUR sulfonada são maiores que para a PUR, devendo estar relacionadas à contribuição dos grupos sulfonato. A PUR sulfonada tem um maior tempo de vida estimado que a PUR, nas temperaturas estudadas. A irradiação das amostras permitiu a verificação da oxidação do segmento do poliol e/ou extensor de cadeia, por meio da diminuição de intensidade das bandas relacionadas a este segmento nos espectros vibracionais e diminuição da cristalinidade por DSC. / Polyurethane (PUR) is a class of polymers that possesses urethane groups [O-C(=O)-NH-] in its structure and that find many applications, including biomedical ones. This variety is due to the use of different monomers in its synthesis. The use of aliphatic isocyanates, one of PUR monomers, is more valuable in applications that demand stability to UV radiation, resistance to hydrolysis, and a greater thermal stability. The aromatic isocyanate-based PUR produces, when processed incorrectly, carcinogenic compounds, a fact that is not observed in the cycloaliphatic isocyanate-based PUR. The PUR modification to use it in biomedical artifacts has been made, among some procedures, through the incorporation of ionic groups into the polymer chain, forming ionomers. The biomedical materials sterilization is made employing ethylene oxide or gamma radiation. The objectives of this work are the synthesis and characterization of PUR and its sulfonated ionomer, both based on a cycloaliphatic isocyanate, as well as the study of the effect of gamma radiation in the polymers. It has been observed the formation of allophanate linkages through the analysis of vibrational spectra and elemental analysis data. Comparing the synthesized PUR and a commercial, amorphous, linear PUR used in biomedical artifacts, it has been noted that the former has crystallinity. The kinetic study of thermal decomposition of PUR allowed to establish the decomposition mechanism of PUR. The thermal stability and crystallinity of sulfonated PUR are greater than of PUR, probably due to the contribution of sulfonic groups. The lifetime of sulfonated PUR is greater than that of PUR, in the temperature range studied. The samples irradiation has permitted the observation of poliol and/or chain extender oxidation, by means of the decreasing of the intensity of the vibrational bands related to these groups and the decreasing of crystallinity in DSC.

DSC

Espectroscopia Raman

Físico-química orgânica

Poliuretana

Radiação gama

TG

Analysis

DSC

Evaluation)

Gamma radiation

Infrared photoacoustic spectroscopy

Infrared spectroscopy (Applications

Organic physicochemistry

Physico-chemical analysis)

Polymers (Materials) (Characteristics

Polyurethane

Raman spectroscopy

Structure

Study

TG

Hochtemperaturinduzierte Mikrostrukturänderungen und Phasenübergänge in nanokristallinen, metastabilen und defektbehafteten Aluminiumoxiden

Thümmler, Martin

03 December 2024

Within the collaborative research center SFB 920 “Multifunctional Filters for Metal Melt Filtration”, the thermally induced formation of metastable aluminum oxides and related microstructural changes were investigated. It was confirmed that the γ-Al₂O₃ phase possesses a defective spinel structure containing Al vacancies that preserve the stoichiometry of this phase. The presence of vacancies fragments apparently the γ-Al₂O₃ crystallites into nanocrystalline domains, which are separated by non-conservative antiphase boundaries (APBs) of the type {100} ¼<110>. These APBs form a 3D network that is randomly distributed over all crystallographically equivalent lattice planes. This phenomenon causes a starlike (and hkl-dependent) broadening of the reciprocal lattice points that correspond to the aluminum sublattice. It was shown that the extent of the broadening of the reciprocal lattice points can be predicted by employing the phase shift factors. With increasing degree of the APBs ordering, the initial streaks representing the broadened reflections start to split, forming superstructure reflections. This superstructure of γ-Al₂O₃ is commonly known as δ-Al₂O₃. Between the ordered APBs, the crystal structure of δ-Al₂O₃ is closely related to the crystal structure of monoclinic θ-Al₂O₃. The phase transition of γ-Al₂O₃/δ-Al₂O₃ to θ-Al₂O₃ proceeds via migration of just three Al³⁺ cations to the neighboring tetrahedral and octahedral sites in the cubic close packed (ccp) oxygen sublattice. The general migration vector is ⅛<111> (γ-Al₂O₃). Diffraction effects associated with different intermediate states can be explained by an improper long-range ordering of equivalent APBs or certain Al³⁺ cations and the local formation of θ-Al₂O₃ within the δ-Al₂O₃ superstructure. The formation of θ-Al₂O₃ is accompanied by an increase of the occupancy of the tetrahedral sites in the oxygen sublattice by the Al³⁺ cations. In surrounding local γ-Al₂O₃ domains, however, some cations migrate from the tetrahedral to the octahedral sites. Thus, the local formation of θ-Al₂O₃ is nearly invisible for the ²⁷Al 1D magic angle spinning nuclear magnetic resonance (MAS NMR) spectroscopy. Still, it was recognized by the 2D multiple quantum (MQ) MAS NMR spectroscopy. A continuous formation of the θ-Al₂O₃ domains was confirmed by the Raman spectroscopy, X-ray diffraction (XRD) and selected area electron diffraction (SAED). The proposed microstructure and transformation models helped to explain the thermal stabilization of the metastable alumina phases by Si-doping. For investigation of the thermally induced phase transitions in metastable alumina phases, boehmite (γ-AlO(OH)) was chosen as the starting compound. However, the metastable alumina phases were also observed in endogenous inclusions present in solidified steel melts. For identification of these phases, a procedure for reconstruction of spherical Kikuchi maps from recorded EBSD patterns was developed.

info:eu-repo/classification/ddc/620

ddc:620

Aluminiumoxide

Mikrostruktur

Phasenumwandlung

Kristallstruktur

Stapelfehler