Ferritin-Based Photo-Oxidation of Biomass for Nanoparticle Synthesis, Bioremediation, and Hydrogen Evolution

Petrucci, Oscar

01 December 2013

The cell is the basic unit of all living organisms. It is an amazing machine capable of self-replicating, growing, and synthesizing and shuttling thousands of compounds. To perform all of these activities the cell needs energy. The original source of energy for all living beings is the Sun. The energy of the sun is collected by the autotrophs (mostly plants) through photosynthesis and stored in the chemical bonds of carbohydrates and lipids through carboxylic acid intermediates; animals use these compounds to obtain the energy for their cells. Most of the energy extracted by the cell comes from the citric acid cycle. Therefore, two crucial energy transfer checkpoints are photosynthesis and citric acid cycle. With growing need for energy, the limited supply of fossil fuel, and the search for a cleaner environment, scientists have turned to the Sun (directly or indirectly through wind, tides, biomass, etc.) to satisfy the needs of modern society trying to reach the dual Holy Grail of energy: harvesting energy through Artificial Photosynthesis and Low Temperature Biomass Oxidation. This work represents one more step toward reaching these Holy Grails. The core reagent used in our technique is ferritin. Ferritin recapitulates some of the essential features of a plant cell: it contains a semiconductor capable of charge separation, like chlorophyll, acts as a membrane to isolate compartments, and has an enzymatic activity that prevents charge build up and oxidative damage. The energy absorbed by ferritin from the artificial “solar” radiation is used to extract reducing equivalents from stable and partially oxidized compounds, mainly carboxylic acids. The energized electrons produced are then used for a number of technical applications, from synthesis of catalytically active nanoparticles, to reductive precipitation of contaminant heavy metals (i.e.: mercury), to hydrogen evolution.

ferritin

artificial photosynthesis

biomass

carboxylic acids

photochemistry

photo catalyst

photosynthesis

renewable energy

gold nanoparticles

mercury

decontamination

bioremediation

silver nanoparticles

hydrogen evolution

hydrogen catalyst

methyl viologen

platinum nanoparticles

palladium nanoparticles

Biochemistry

Chemistry

Développement d’une méthode d’extraction et d’analyse de nanoparticules d’argent dans le boeuf haché par spectrométrie de masse à plasma à couplage inductif en mode particule unique

Chalifoux, Alexandre

05 1900

La caractérisation de nanomatériaux dans des matrices alimentaires et animales suscite un intérêt scientifique important afin d’évaluer les risques potentiels de l’exposition liés à l’utilisation grandissante des nanomatériaux par plusieurs industries, y compris un certain nombre d’applications agroalimentaires. Un facteur limitant à l’étude et la réglementation des nanomatériaux dans des matrices complexes telle que la nourriture est l’absence de méthodes standardisées pour l’extraction et l’analyse de nanoparticules, tout en évitant l’altération de certaines caractéristiques physicochimiques des nanoparticules. Les travaux présentés dans ce mémoire abordent l’optimisation de plusieurs approches de préparation d’échantillon (hydrolyse enzymatique et alcaline) pour l’extraction de nanoparticules d’Ag préalablement équilibrées dans une matrice de boeuf haché mi-maigre. Les nanoparticules extraites ont été analysées par spectrométrie de masse à plasma à couplage inductif en mode particule unique (SP-ICP-MS) permettant la mesure de leur taille et concentration, mais aussi de la concentration en métal dissous, le tout à de très faibles concentrations (de l’ordre du ng/L). La validation de l’analyse par SP-ICP-MS a été réalisée par évaluation de la répétabilité, de la détermination des limites de détection et par une investigation de l’influence du traitement de données sur l’interprétation des résultats. Les pertes de nanoparticules lors de la préparation des échantillons ont été minimisées par l’identification et l’optimisation de paramètres clés tels que la composition du médium d’extraction, l’utilisation d’ultrasons et de la manipulation de l’échantillon après dégradation de la matrice. Les meilleurs recouvrements ont été obtenus par hydrolyse alcaline de la matrice en utilisant de l’hydroxyde de tetramethylammonium (TMAH), mais les échantillons obtenus étaient moins stables et plus susceptibles aux altérations des propriétés physicochimiques des nanoparticules que pour la dégradation par hydrolyse enzymatique utilisant lipase et pancréatine de porc. / The regulation and characterization of nanomaterials in foods and animal matrices are of great interest due to the potential risks associated with their exposure and the increasing number of instances where they are used within the food industry. One factor limiting the scientifically rigorous regulation of nanoparticles in foods is the lack of standardized procedures for the extraction of nanoparticles (NP) from complex matrices, without alteration of their physico-chemical properties. To this end, two sample preparation approaches (enzymatic- and alkaline-based hydrolyses) were tested and optimized in order to extract 40 nm Ag NP, following their equilibration with a fatty ground beef matrix. Extracted NP were characterized using single particle inductively coupled plasma mass spectrometry (SP-ICP-MS), allowing the determination of NP size and concentrations and also dissolved metal concentrations at trace levels. Validation of the SP-ICP-MS analysis was achieved by an evaluation of the repeatability and accuracy and by a determination of the various detection limits. Finally, we also looked into the influence of data treatment on interpretation of the results. NP losses during the sample preparation were minimized by identifying and optimizing key parameters such as the composition of the extraction media, usage of ultrasonication or the handling of the sample after separation from the undigested matter, among other points. The alkaline approach using TMAH (tetramethylammonium hydroxide) was found to have the highest recoveries, however processed samples were found to be less stable and more prone to alteration of the Ag NP physicochemical characteristics than samples processed using an enzymatic digestion based upon pork pancreatin and lipase.

Nanoparticules d’argent

Icp-ms

Nanomatériaux

Proteinase-K

TMAH

Silver nanoparticles

Single-particle ICP-MS

Icp-ms en mode particule unique

Nanomaterials

Enzymatic extraction

Alkaline hydrolysis

Fodd

Nourriture

Extraction enzymatique

Hydrolyse alcaline

Plasmon catalyst dispersed on carbonised pinecone for enhanced degradation of organic contaminants

Olalekan, Sanni Saheed

11 1900

Ph. D. (Department of Chemistry, Faculty of Applied and Computer Sciences), Vaal University of Technology. / Aromatic organic contaminants are difficult to biodegrade, and thus effective green technologies are required to remove these pollutants from the ecosystem. Tetracycline antibiotic, an organic water pollutant, can be degraded by heterogeneous photocatalysis using an appropriate catalyst, with capability in converting the visible light energy into active species. The thesis focused on silver nanoparticles anchored on silver bromide (Ag/AgBr) as a plasmonic catalyst dispersed on activated carbon (ACK), were used as a photocatalyst (AABR-ACK) in tetracycline removal. The aim is to develop a catalyst that is active in low intensity visible light, whilst the addition of activated carbon will increase the light absorption and separate the charge pairs, after the photocatalyst has been excited by the visible light. The activated carbons were derived from pinecone pyrolyzed in a microwave. The pinecone mass to potassium hydroxide impregnation ratio and microwave pyrolysis time influenced the activated carbon properties. An impregnation ratio of 2.24 and microwave pyrolysis time of 16 minutes at constant microwave power of 400 W yielded the activated carbon with the best-developed porous structure and electrochemical properties. This activated carbon was used during the optimisation of the Ag/AgBr activated carbon (AABR-ACK) catalysts preparation using a thermal polyol precipitation method and response surface methodology. The most active catalyst was the AABR-ACK 11 obtained by a preparation temperature of 140 ºC, time (17.50 minutes), mass of surfactant and activated carbon (0.26 g and 0.03 g) respectively. This catalyst had an ordered nanospheres morphology, reduced electron-hole recombination rate, better electrochemical properties and exhibited enhanced activity on the tetracycline antibiotic removal in comparison to other Ag/AgBr activated carbon catalysts. A percentage degradation of 92% was obtained in 180 minutes were obtained with the AABR-ACK 11 catalyst. The photocatalyst prepared using the best activated carbon derived from pinecone developed in this study was compared to photocatalysts prepared using commercial activated carbon and biochar. The Ag/AgBr activated carbon catalysts using pinecone-derived activated carbon degraded the tetracycline to 92%, which is significantly higher than the percentage degradations (80% and 74%) for the catalyst prepared using commercial activated carbon and biochar catalysts respectively. The higher activity of the Ag/AgBr activated carbon catalysts using pinecone-derived activated carbon was due to the conductive attributes of the catalyst support for accelerated transfer of photo-induced electrons. The Ag/AgBr activated carbon catalysts using pinecone- derived activated carbon also exhibited better performance on tetracycline removal when compared to photocatalysts reported in literature. Two catalyst preparation methods, thermal polyol and deposition precipitation, were compared. The thermal polyol method yielded a more active catalyst for the degradation of the tetracycline in comparison to the deposition precipitation method. The degradation reaction conditions such as pH, light intensity and degradation temperature influenced the rate of the reaction. The highest rate of degradation was obtained at a pH of seven, white light and 40 ºC temperature. The intermediate products formed because of hydroxylation, deamination, demethylation and dehydration during the photocatalytic degradation of tetracycline antibiotics were identified using liquid chromatography mass spectrometer. Quenching experiments with hydroxyl, hole, and superoxide anion species showed that the most important radical responsible for the tetracycline degradation was the superoxide anion radical.

Plasmon catalyst

Degradation of organic contaminants

Carbonised pinecone

Green technologies

Silver nanoparticles

Photocatalyst

Photocatalytic degradation

Tetracycline antibiotics

Visible-light photocatalytic

Water contamination

Dissertations, Academic -- South Africa

Nanoparticles

Silver

Catalysts

Organic water pollutants

Hierarchical Porous Structures with Aligned Carbon Nanotubes as Efficient Adsorbents and Metal-Catalyst Supports

Vijwani, Hema

04 June 2015

No description available.

Engineering

Materials Science

Nanotechnology

Nanoscience

Environmental Studies

Estudos das propriedades estruturais e ópticas de vidros teluritos / Studies of the structural and optical properties of the tellurite glasses

Giehl, Júlia Maria

25 February 2011

Vidros teluritos são considerados fortes candidatos para aplicações em lasers e óptica não linear devido a importantes características, como o elevado índice de refração, baixa energia de fônons, baixa temperatura de transição vítrea e sua fácil preparação. Neste trabalho foram produzidas amostras dos sistemas vítreos TeO2- ZnO-Na2O, TeO2-Nb2O5-Na2O e Te2O-Na2O incluindo ou não dopagens de AgNO3 para estudos estruturais e ópticos. As propriedades estruturais e os mecanismos de recombinação destes vidros foram estudados por meio das técnicas de ressonância paramagnética eletrônica, termoluminescência e correntes de despolarização termicamente estimuladas. Já as propriedades ópticas como o coeficiente de absorção linear, índice de refração linear e não linear foram estudadas por meio das técnicas de absorção óptica, acoplamento de prismas e varredura Z. Foram ainda desenvolvidos estudos da precipitação de nanopartículas de prata para o sistema TeO2-ZnO-Na2O com dopagens de AgNO3 com diferentes temperaturas de tratamento térmico. A caracterização das nanopartículas metálicas foi realizada por meio da técnica de absorção óptica auxiliada por microscopia eletrônica de transmissão e espectrometria de energia dispersiva. Foram observadas por ressonância paramagnética eletrônica quatro respostas paramagnéticas dos vidros irradiados com raio , sendo uma de natureza desconhecida e as outras três identificadas como g¹, g² e g³ atribuídas respectivamente ao centro de buraco do telúrio e do oxigênio, centro de buraco do oxigênio terminal e centro de elétron do telúrio. Foi proposto ainda um modelo para explicar os mecanismos de formação destes centros. A partir dos resultados de termoluminescência observou-se que os processos de recombinação destes centros de defeitos são não radioativos. Neste projeto foram estudados pela primeira vez na literatura os fenômenos de polarização e despolarização em vidros teluritos, com e sem irradiação gama, por meio da técnica de correntes de despolarização termicamente estimuladas. Quanto às propriedades ópticas, foi investigada a influência da adição de prata dos sistemas vítreos TeO2-ZnO-Na2O e TeO2-Nb2O5-Na2O em relação à energia do gap, a cauda de Urbach, índice de refração linear e não linear.Nos resultados de varredura Z do sistema vítreo TeO2-Nb2O5-Na2O foi observado o aumento da assimetria na curva com aumento da adição de AgNO3 Este fenômeno foi explicado por meio de uma adaptação do modelo de Sumi para processos não radiativos, responsáveis pelo aumento do caráter térmico do índice de refração não linear. Por fim um modelo foi criado para explicar a precipitação de nanopartículas de prata na matriz vítrea TeO2-ZnO-Na2O mediante tratamento térmico. / Tellurite glasses are considered powerful candidates for applications in lasers and nonlinear optics due to their important properties such as high refractive index, low phonon energy, relatively low glass transition temperature and easy glass production at room atmosphere. In this work glass samples of the systems ZnO-Na2O, TeO2-Nb2O5-Na2O and Te2O-Na2O were produced, including or not the AgNO3 doping for the structural and optical study purposes. The structural properties and the recombination mechanisms of these glasses were studied by means of the techniques of electron paramagnetic resonance, thermoluminescence and thermally stimulated depolarization currents. The optical properties such as the optical linear absorption coefficient, linear and nonlinear refractive index were studied by means of the optical absorption techniques, prism coupling and Z-scan. Further studies were developed on the precipitation of silver nanoparticles embedded in the glass system TeO2-ZnO-Na2O doped with AgNO3, by means of thermal treatments at different temperatures. The characterization of the metallic nanoparticles was carried out by optical absorption aided by transmission electron microscopy and dispersive energy spectroscopy. Four paramagnetic responses were observed by electron paramagnetic resonance of the -irradiated glasses, one not yet identified and the other three identified as g0, g1 and g3 attributed respectively to the tellurium-oxygen hole center, non-bridging oxygen hole center and tellurium electron center. A model to explain the formation mechanisms of these centers was proposed. The thermoluminescence results indicated that the recombination processes of these centers are non-radiative. This is the first study that deals with polarization and depolarization phenomena in tellurite glasses with and without gamma irradiation, by the technique of thermally stimulated depolarization currents. In what regards the optical properties of the glass systems TeO2-ZnONa2O and TeO2-Nb2O5-Na2O, the effect of the silver doping on the gap energy, Urbach tail, linear and nonlinear refractive indices were investigated. Through the Z-scan technique results of the glass system TeO2-Nb2O5-Na2O, an increasing asymmetry of the curve, with increasing AgNO3 content was observed. This phenomenon was explained through an adaptation of Sumi´s model for non-radiative processes, applied to a silver doped insulating glass, to explain the thermal character of the nonlinear refractive index. Finally, a model was developed to explain the silver nanoparticles precipitation in the TeO2-ZnO-Na2O glass matrix submitted to thermal treatment.

Absorção óptica

Centros de defeitos

Defect centers

Electron paramagnetic resonance

Índice de refração não linear

Microscopia eletrônica de transmissão

Nanopartículas de prata

Nonlinear refractive index

Optical absorption

Ressonância paramagnética eletrônica

Silver nanoparticles

Tellurite glasses

Termoluminescência

Thermoluminescence

Transmission electron microscopy

Varredura Z

Vidros teluritos

Z-scan

Oberflächenverstärkte Hyper-Raman-Streuung (SEHRS) und oberflächenverstärkte Raman-Streuung (SERS) für analytische Anwendungen

Gühlke, Marina

02 August 2016

Hyper-Raman-Streuung folgt anderen Symmetrieauswahlregeln als Raman-Streuung und profitiert als nicht-linearer Zweiphotonenprozess noch mehr von verstärkten elektromagnetischen Feldern an der Oberfläche plasmonischer Nanostrukturen. Damit könnte die oberflächenverstärkte Hyper-Raman-Streuung (SEHRS) praktische Bedeutung in der Spektroskopie erlangen. Durch die Kombination von SEHRS und oberflächenverstärkter Raman-Streuung (SERS) können komplementäre Strukturinformationen erhalten werden. Diese eignen sich aufgrund der Lokalisierung der Verstärkung auf die unmittelbare Umgebung der Nanostrukturen besonders für die Charakterisierung der Wechselwirkung zwischen Molekülen und Metalloberflächen. Ziel dieser Arbeit war es, ein tieferes Verständnis des SEHRS-Effekts zu erlangen und dessen Anwendbarkeit für analytische Fragestellungen einzuschätzen. Dazu wurden SEHRS-Experimente mit Anregung bei 1064 nm und SERS-Experimente mit Anregung bei derselben Wellenlänge sowie mit Anregung bei 532 nm - für eine Detektion von SEHRS und SERS im gleichen Spektralbereich - durchgeführt. Als Beispiel für nicht-resonante Anregung wurden die vom pH-Wert abhängigen SEHRS- und SERS-Spektren von para-Mercaptobenzoesäure untersucht. Mit diesen Spektren wurde die Wechselwirkung verschiedener Silbernanostrukturen mit den Molekülen charakterisiert. Anhand von beta-Carotin wurden Einflüsse von Resonanzverstärkung im SEHRS-Experiment durch die gleichzeitige Anregung eines molekularen elektronischen Übergangs untersucht. Dabei wurde durch eine Thiolfunktionalisierung des Carotins eine intensivere Wechselwirkung mit der Silberoberfläche erzielt, sodass nicht nur resonante SEHRS- und SERS-Spektren, sondern auch nicht-resonante SERS-Spektren von Carotin erhalten werden konnten. Die Anwendbarkeit von SEHRS für hyperspektrale Kartierung in Verbindung mit Mikrospektroskopie wurde durch die Untersuchung von Verteilungen verschiedener Farbstoffe auf strukturierten plasmonischen Oberflächen demonstriert. / Hyper-Raman scattering follows different symmetry selection rules than Raman scattering and, as a non-linear two-photon process, profits even more than Raman scattering from enhanced electromagnetic fields at the surface of plasmonic nanostructures. Surface-enhanced hyper-Raman scattering (SEHRS) could thus gain practical importance for spectroscopy. The combination of SEHRS and surface-enhanced Raman scattering (SERS) offers complementary structural information. Specifically, due to the localization of the enhancement to the close proximity of the nanostructures, this information can be utilized for the characterization of the interaction between molecules and metal surfaces. The aim of this work was to increase the understanding of the SEHRS effect and to assess its applicability to answer analytical questions. For that purpose, SEHRS experiments with excitation at 1064 nm and SERS experiments with excitation at the same wavelength, as well as with excitation at 532 nm - to detect SEHRS and SERS in the same spectral region - were conducted. As an example for non-resonant excitation, pH-dependent SEHRS and SERS spectra of para-mercaptobenzoic acid were examined. Based on these spectra, the interaction of different silver nanostructures with the molecules was characterized. beta-Carotene was used to study the influence of resonance enhancement by the excitation of a molecular electronic transition during SEHRS experiments. By the thiol-functionalization of carotene, a more intense interaction with the silver surface was achieved, which enables to obtain not only resonant SEHRS and SERS but also non-resonant SERS spectra of carotene. Hyperspectral SEHRS imaging in combination with microspectroscopy was demonstrated by analyzing the distribution of different dyes on structured plasmonic surfaces.

Spektroskopie

hyperspektrale Bildgebung

Silbernanopartikel

beta-Carotin

para-Mercaptobenzoesäure

Kristallviolett

Malachitgrün

spectroscopy

hyperspectral imaging

surface-enhanced Raman scattering (SERS)

silver nanoparticles

beta-carotene

para-mercaptobenzoic acid

crystal violet

malachite green

540 Chemie

30 Chemie

UH 5715

VG 9307

ddc:540

Modulation of Nanostructures in the Solid and Solution States and under an Electron Beam

Sanyal, Udishnu

January 2013

Among various nanomaterials, metal nanoparticles are the widely studied ones because of their pronounced distinct properties arising in the nanometer size regime, which can be tailored easily by tuning predominantly their size and shape. During the past few decades, scientists are engaged in developing new synthetic methodologies for the synthesis of metal nanoparticles which can be divided into two broad categories: i) top-down approach, utilizing physical methods and ii) bottom-up approach, employing chemical methods. As the chemical methods offer better control over particle size, numerous chemical methods have been developed to obtain metal nanoparticles with narrow size distribution. However, these two approaches have their own merits and demerits; they are not complementary to each other and also not sustainable for real time applications. Recent focus on the synthesis of metal nanoparticles is towards the development of green and sustainable synthetic methodologies. A solid state route is an exciting prospect in this direction because it eliminates usage of organic solvents thus, makes the overall process green and at the same time leads to the realization of large quantity of the materials, which is required for many applications. However, the major obstacle associated with the development of a solid state synthetic route is the lack of fundamental understanding regarding the formation mechanism of the nanoparticles in the solid state. Additionally, due to the heterogeneity present in the solid mixture, it is very difficult to ensure the proximity between the capping agent and nuclei which plays the most decisive role in the growth process. Recently, employment of amine–borane compounds as reducing agents emerged as a better prospect towards the development of sustainable synthetic routes for metal nanoparticles because they offer a variety of advantages over the traditional borohydrides. Being soluble in organic medium, amine– borane allows the reaction to be carried out in a single phase and due to its mild reducing ability a much better control over the nucleation and growth processes is realized. However, the most exciting feature of these compounds is that their reducing ability is not only limited to the solution state, they can also bring out the reduction of metal ions in the solid state. With the availability of a variety of amine–boranes of varying reducing ability, it opens up a possibility to modulate the nanostructure in both solid and solution states by a judicious choice of reducing agent. Although our current understanding regarding the growth behavior of nanoparticles has advanced remarkably, however, most often it is some classical model which is invoked to understand these processes. With the recent developments in in situ transmission electron microscopy techniques, it is now possible to unravel more complex growth trajectories of nanoparticles. These studies not only expand the scope of the present knowledge but also opens up possibilities for many future developments. Objectives • To develop an atom economy solid state synthetic methodology for the synthesis of metal nanoparticles employing amine–boranes as reducing agents. • To gain a mechanistic insight into the formation mechanisms of nanoparticles in the solid state by using amine–boranes with differing reducing ability. • Synthesis of bimetallic nanoparticles as well as supported metal nanoparticles in the solid state using ammonia borane as the reducing agent. • To develop a new in situ seeding growth methodology for the synthesis of core@shell nanoparticles composed of noble metals by employing a very weak reducing agent, trimethylamine borane and their transformation to their thermodynamically stable alloy counterparts. • Synthesis of highly monodisperse ultra-small colloidal calcium nanoparticles with different capping agents such as hexadecylamine, octadecylamine, poly(vinylpyrrolidone) and a combination of hexadecylamine/poly(vinylpyrrolidone) using the solvated metal atom dispersion (SMAD) method. To study the coalescence behavior of a pair of calcium nanoparticles under an electron beam by employing in situ TEM technique. Significant results An atom economy solid state synthetic route has been developed for the synthesis of metal nanoparticles from simple metal salts using amine–boranes as reducing agents. Amine–borane plays a dual role here: acts as a reducing agent thus brings out the reduction of metal ions and decomposes simultaneously to generate B-N based compounds which acts as a capping agent to stabilize the particles in the nanosize regime. This essentially minimizes the number of reagents used and hence simplifying and eliminating the purification procedures and thus, brings out an atom economy to the overall process. Additionally, as the reactions were carried out in the solid state, it eliminates use of organic solvents which have many adverse effects on the environment, thus makes the synthetic route, green. The particle size and the size distribution were tuned by employing amine–boranes with differing reducing abilities. Three different amine–boranes have been employed: ammonia borane (AB), dimethylamine borane (DMAB), and trimethylamine borane (TMAB) whose reducing ability varies as AB > DMAB >> TMAB. It was found that in case of AB, it is the polyborazylene or BNHx polymer whereas, in case of DMAB and TMAB, the complexing amines act as the stabilizing agents. Several controlled studies also showed that the rate of addition of metal salt to AB is the crucial step and has a profound effect on the particle size as well as the size distribution. It was also found that an optimum ratio of amine–borane to metal salt is important to realize the smallest possible size with narrowest size distribution. Whereas, use of AB and TMAB resulted in the smallest sized particles with best size distribution, usage of DMAB provided larger particles that are also polydisperse in nature. Based on several experiments along with available data, the formation mechanism of metal nanoparticles in the solid state has been proposed. Highly monodisperse Cu, Ag, Au, Pd, and Ir nanoparticles were realized using the solid state route described herein. The solid state route was extended to the synthesis of bimetallic nanoparticles as well as supported metal nanoparticles. Employment of metal nitrate as the metal precursor and ammonia borane as the reducing agent resulted in highly exothermic reaction. The heat evolved in this reaction was exploited successfully towards mixing of the constituent elements thus allowing the alloy formation to occur at much lower temperature (60 oC) compared to the traditional solid state metallurgical methods (temperature used in these cases are > 1000 oC). Synthesis of highly monodisperse 2-3 nm Cu/Au and 5-8 nm Cu/Ag nanoparticles were demonstrated herein. Alumina and silica supported Pt and Pd nanoparticles have also been prepared. Use of ammonia borane as the reducing agent in the solid state brought out the reduction of metal ions to metal nanoparticles and the simultaneous generation of BNHx polymer which encapsulates the metal (Pt and Pd) nanoparticles supported on support materials. Treatment of these materials with methanol resulted in the solvolysis of BNHx polymer and its complete removal to finally provide metal nanoparticles on the support materials. An in situ seeding growth methodology for the synthesis of bimetallic nanoparticles with core@shell architecture composed of noble metals has been developed using trimethylamine borane (TMAB) as the reducing agent. The key idea of this synthetic procedure is that, TMAB being a weak reducing agent is able to differentiate the smallest possible window of reduction potential and hence reduces the metal ions sequentially. A dramatic solvent effect was noted in the preparation of Ag nanoparticles: Ag nanoparticles were obtained at room temperature when dry THF was used as the solvent whereas, reflux condition was required to realize the same using wet THF as the solvent. However, no such behavior was noted in the preparation of Au and Pd nanoparticles wherein Au and Pd nanoparticles were obtained at room temperature and reflux conditions, respectively. This difference in reduction behavior was successfully exploited to synthesize Au@Ag, Ag@Au, and Ag@Pd nanoparticles. All these core@shell nanoparticles were further transformed to their alloy counterparts under very mild conditions reported to date. Highly monodisperse, ultrasmall, colloidal Ca nanoparticles with a size regime of 2-4 nm were synthesized using solvated metal atom dispersion (SMAD) method and digestive ripening technique. Hexadecylamine (HDA) was used as the stabilizing agent in this case. Employment of capping agent with a longer chain length, octadecylamine afforded even smaller sized particles. However, when poly(vinylpyrrolidone) (PVP), a branched chain polymer was used as the capping agent, agglomerated particles were realized together with small particles of 3-6 nm. Use of a combination of PVP and HDA resulted in spherical particles of 2-3 nm size with narrow size distribution. Growth of Ca nanoparticles via colaesence mechanism was observed under an electron beam. Employing in situ transmission electron microscopy technique, real time coalescence between a pair of Ca nanoparticles were detected and details of coalescence steps were analyzed.

Nanomaterials

Metal Nanoparticles - Synthesis

Amine-Boranes

Bimetallic Nanoparticles - Synthesis

Core@Shell Nanoparticles - Synthesis

Calcium Nanoparticles - Synthesis

Metal Nanocomposites

Alloy Nanoparticles

Nanostructures, Solid State - Modulation

Metal Nanoparticles - Synthesis

Silver Nanoparticles

Gold Nanoparticles

Metal Nanocatalysts

Ammonia Borane

Nanotechnology

Estudos das propriedades estruturais e ópticas de vidros teluritos / Studies of the structural and optical properties of the tellurite glasses

Júlia Maria Giehl

25 February 2011

Vidros teluritos são considerados fortes candidatos para aplicações em lasers e óptica não linear devido a importantes características, como o elevado índice de refração, baixa energia de fônons, baixa temperatura de transição vítrea e sua fácil preparação. Neste trabalho foram produzidas amostras dos sistemas vítreos TeO2- ZnO-Na2O, TeO2-Nb2O5-Na2O e Te2O-Na2O incluindo ou não dopagens de AgNO3 para estudos estruturais e ópticos. As propriedades estruturais e os mecanismos de recombinação destes vidros foram estudados por meio das técnicas de ressonância paramagnética eletrônica, termoluminescência e correntes de despolarização termicamente estimuladas. Já as propriedades ópticas como o coeficiente de absorção linear, índice de refração linear e não linear foram estudadas por meio das técnicas de absorção óptica, acoplamento de prismas e varredura Z. Foram ainda desenvolvidos estudos da precipitação de nanopartículas de prata para o sistema TeO2-ZnO-Na2O com dopagens de AgNO3 com diferentes temperaturas de tratamento térmico. A caracterização das nanopartículas metálicas foi realizada por meio da técnica de absorção óptica auxiliada por microscopia eletrônica de transmissão e espectrometria de energia dispersiva. Foram observadas por ressonância paramagnética eletrônica quatro respostas paramagnéticas dos vidros irradiados com raio , sendo uma de natureza desconhecida e as outras três identificadas como g¹, g² e g³ atribuídas respectivamente ao centro de buraco do telúrio e do oxigênio, centro de buraco do oxigênio terminal e centro de elétron do telúrio. Foi proposto ainda um modelo para explicar os mecanismos de formação destes centros. A partir dos resultados de termoluminescência observou-se que os processos de recombinação destes centros de defeitos são não radioativos. Neste projeto foram estudados pela primeira vez na literatura os fenômenos de polarização e despolarização em vidros teluritos, com e sem irradiação gama, por meio da técnica de correntes de despolarização termicamente estimuladas. Quanto às propriedades ópticas, foi investigada a influência da adição de prata dos sistemas vítreos TeO2-ZnO-Na2O e TeO2-Nb2O5-Na2O em relação à energia do gap, a cauda de Urbach, índice de refração linear e não linear.Nos resultados de varredura Z do sistema vítreo TeO2-Nb2O5-Na2O foi observado o aumento da assimetria na curva com aumento da adição de AgNO3 Este fenômeno foi explicado por meio de uma adaptação do modelo de Sumi para processos não radiativos, responsáveis pelo aumento do caráter térmico do índice de refração não linear. Por fim um modelo foi criado para explicar a precipitação de nanopartículas de prata na matriz vítrea TeO2-ZnO-Na2O mediante tratamento térmico. / Tellurite glasses are considered powerful candidates for applications in lasers and nonlinear optics due to their important properties such as high refractive index, low phonon energy, relatively low glass transition temperature and easy glass production at room atmosphere. In this work glass samples of the systems ZnO-Na2O, TeO2-Nb2O5-Na2O and Te2O-Na2O were produced, including or not the AgNO3 doping for the structural and optical study purposes. The structural properties and the recombination mechanisms of these glasses were studied by means of the techniques of electron paramagnetic resonance, thermoluminescence and thermally stimulated depolarization currents. The optical properties such as the optical linear absorption coefficient, linear and nonlinear refractive index were studied by means of the optical absorption techniques, prism coupling and Z-scan. Further studies were developed on the precipitation of silver nanoparticles embedded in the glass system TeO2-ZnO-Na2O doped with AgNO3, by means of thermal treatments at different temperatures. The characterization of the metallic nanoparticles was carried out by optical absorption aided by transmission electron microscopy and dispersive energy spectroscopy. Four paramagnetic responses were observed by electron paramagnetic resonance of the -irradiated glasses, one not yet identified and the other three identified as g0, g1 and g3 attributed respectively to the tellurium-oxygen hole center, non-bridging oxygen hole center and tellurium electron center. A model to explain the formation mechanisms of these centers was proposed. The thermoluminescence results indicated that the recombination processes of these centers are non-radiative. This is the first study that deals with polarization and depolarization phenomena in tellurite glasses with and without gamma irradiation, by the technique of thermally stimulated depolarization currents. In what regards the optical properties of the glass systems TeO2-ZnONa2O and TeO2-Nb2O5-Na2O, the effect of the silver doping on the gap energy, Urbach tail, linear and nonlinear refractive indices were investigated. Through the Z-scan technique results of the glass system TeO2-Nb2O5-Na2O, an increasing asymmetry of the curve, with increasing AgNO3 content was observed. This phenomenon was explained through an adaptation of Sumi´s model for non-radiative processes, applied to a silver doped insulating glass, to explain the thermal character of the nonlinear refractive index. Finally, a model was developed to explain the silver nanoparticles precipitation in the TeO2-ZnO-Na2O glass matrix submitted to thermal treatment.

Absorção óptica

Centros de defeitos

Índice de refração não linear

Microscopia eletrônica de transmissão

Nanopartículas de prata

Ressonância paramagnética eletrônica

Termoluminescência

Varredura Z

Vidros teluritos

Defect centers

Electron paramagnetic resonance

Nonlinear refractive index

Optical absorption

Silver nanoparticles

Tellurite glasses

Thermoluminescence

Transmission electron microscopy

Z-scan

From Transformation to Therapeutics : Diverse Biological Applications of Shock Waves

Ganadhas, Divya Prakash

January 2014

Chapter–I Introduction Shock waves appear in nature whenever the different elements in a fluid approach one another with a velocity larger than the local speed of sound. Shock waves are essentially non-linear waves that propagate at supersonic speeds. Such disturbances occur in steady transonic or supersonic flows, during explosions, earthquakes, tsunamis, lightening strokes and contact surfaces in laboratory devices. Any sudden release of energy (within few μs) will invariably result in the formation of shock wave since it is one of the efficient mechanisms of energy dissipation observed in nature. The dissipation of mechanical, nuclear, chemical, and electrical energy in a limited space will result in the formation of a shock wave. However, it is possible to generate micro-shock waves in laboratory using different methods including controlled explosions. One of the unique features of shock wave propagation in any medium (solid, liquid or gases) is their ability to instantaneously enhance pressure and temperature of the medium. Shock waves have been successfully used for disintegrating kidney stones, non-invasive angiogenic therapy and osteoporosis treatment. In this study, we have generated a novel method to produce micro-shock waves using micro-explosions. Different biological applications were developed by further exploring the physical properties of shock waves. Chapter – II Bacterial transformation using micro-shock waves In bacteria, uptake of DNA occurs naturally by transformation, transduction and conjugation. The most widely used methods for artificial bacterial transformation are procedures based on CaCl2 treatment and electroporation. In this chapter, controlled micro-shock waves were harnessed to develop a unique bacterial transformation method. The conditions have been optimized for the maximum transformation efficiency in E. coli. The highest transformation efficiency achieved (1 × 10-5 transformants per cell) was at least 10 times greater than the previously reported ultrasound mediated transformation (1 × 10-6 transformants per cell). This method has also been successfully employed for the efficient and reproducible transformation of Pseudomonas aeruginosa and Salmonella Typhimurium. This novel method of transformation has been shown to be as efficient as electroporation with the added advantage of better recovery of cells, economical (40 times cheaper than commercial electroporator) and growth-phase independent transformation. Chapter – III Needle-less vaccine delivery using micro-shock waves Utilizing the instantaneous mechanical impulse generated behind the micro-shock wave during controlled explosion, a novel non-intrusive needleless vaccine delivery system has been developed. It is well established, that antigens in the epidermis are efficiently presented by resident Langerhans cells, eliciting the requisite immune response, making them a good target for vaccine delivery. Unfortunately, needle free devices for epidermal delivery have inherent problems from the perspective of patient safety and comfort. The penetration depth of less than 100 µm in the skin can elicit higher immune response without any pain. Here the efficient utilization of the device for micro-shock wave mediated vaccination was demonstrated. Salmonella enterica serovar Typhimurium vaccine strain pmrG-HM-D (DV-STM-07) was delivered using our device in the murine salmonellosis model and the effectiveness of the delivery system for vaccination was compared with other routes of vaccination. The device mediated vaccination elicits better protection as well as IgG response even in lower vaccine dose (ten-fold lesser), compare to other routes of vaccination. Chapter – IV In vitro and in vivo biofilm disruption using shock waves Many of the bacteria secrete highly hydrated framework of extracellular polymer matrix on encountering suitable substrates and get embedded within the matrix to form biofilm. Bacterial colonization in biofilm form is observed in most of the medical devices as well as during infections. Since these bacteria are protected by the polymeric matrix, antibiotic concentration of more than 1000 times of the MIC is required to treat these infections. Active research is being undertaken to develop antibacterial coated medical implants to prevent the formation of biofilm. Here, a novel strategy to treat biofilm colonization in medical devices and infectious conditions by employing shock waves was developed. Micro-shock waves assisted disintegration of Salmonella, Pseudomonas and Staphylococcus biofilm in urinary catheters was demonstrated. The biofilm treated with micro-shock waves became susceptible to antibiotics, whereas the untreated was resistant. Apart from medical devices, the study was extended to Pseudomonas lung infection model in mice. Mice exposed to shock waves responded well to ciprofloxacin while ciprofloxacin alone could not rescue the mice from infection. All the mice survived when antibiotic treatment was provided along with shock wave exposure. These results clearly demonstrate that shock waves can be used along with antibiotic treatment to tackle chronic conditions resulting from biofilm formation in medical devices as well as biological infections. Chapter – V Shock wave responsive drug delivery system for therapeutic application Different systems have been used for more efficient drug delivery as well as targeted delivery. Responsive drug delivery systems have also been developed where different stimuli (pH, temperature, ultrasound etc.) are used to trigger the drug release. In this study, a novel drug delivery system which responds to shock waves was developed. Spermidine and dextran sulfate was used to develop the microcapsules using layer by layer method. Ciprofloxacin was loaded in the capsules and we have used shock waves to release the drug. Only 10% of the drug was released in 24 h at pH 7.4, whereas 20% of the drug was released immediately after the particles were exposed to shock waves. Almost 90% of the drug release was observed when the particles were exposed to shock waves 5 times. Since shock waves can be used to induce angiogenesis and wound healing, Staphylococcus aureus skin infection model was used to show the effectiveness of the delivery system. The results show that shock wave can be used to trigger the drug release and can be used to treat the wound effectively. A brief summary of the studies that does not directly deal with the biological applications of shock waves are included in the Appendix. Different drug delivery systems were developed to check their effect in Salmonella infection as well as cancer. It was shown for the first time that silver nanoparticles interact with serum proteins and hence the antimicrobial properties are affected. In a nutshell, the potential of shock waves was harnessed to develop novel experimental tools/technologies that transcend the traditional boundaries of basic science and engineering.

Shock Waves

Micro-Shock Waves

Bacterial Transformation

Needle-less Vaccine Delivery

Biofilm Distruption

Bacterial Biofilms-Effect of Shock Waves

Biofilm Infection

Shock Wave Therapy

Chitosan-dextran Sulphate Nanocapsule

Silver Nanoparticles

Chitosan/heparin Nanocapsules

Silica Nanoparticles

Curcumin

Microbiology

Caractérisations optiques (LBIC, LBIV) et validation d’encres pour des cellules et des modules solaires photovoltaïques organiques / Optical characterizations (LBIC, LBIV) and validation of inks for organic photovoltaic cells and modules

Garuz, Richard

22 September 2015

Les travaux de cette thèse sont en rapport avec la caractérisation de cellules solaires organiques et se déclinent suivant 3 axes :- Dans le cadre du projet IMPCELPHOTOR, nous avons développé un banc de caractérisation LBIC/LBIV permettant de cartographier des dispositifs OPV afin de visualiser et d’identifier les défauts de fonctionnement.- Dans le cadre du projet Européen SPrinTronics, nous avons travaillé sur l’amélioration des électrodes. Pour l’électrode collectrice d’électrons, nous avons sélectionné, testé et validé des encres métalliques à base de nanoparticules d’argent compatibles avec l’impression jet d’encre et permettant de réaliser des dispositifs OPV fonctionnels. Pour l’électrode collectrice de trous, nous avons testé des encres à base de nanofils d’argent et de nanotubes de carbone afin de remplacer l’ITO. Des résultats satisfaisants ont été obtenus avec une encre à base de nanofils d’argent. Cette dernière permet de réaliser des cellules semi-transparentes fonctionnelles sur verre et sur plastique. - Un travail sur l’aspect couleur d’un dispositif OPV a été mené au sein du projet PHASME. Nous avons mis en œuvre différentes techniques afin de modifier la couleur d’un dispositif OPV sans détruire ses performances photovoltaïques, le but étant de réaliser des modules polychromes. Nous avons développé simultanément un logiciel de colorimétrie permettant de contrôler et de prévoir le rendu de couleur dû à l’ajout de filtre coloré sur le dispositif OPV. / The work of this thesis is related to the characterization of organic solar cells and is structured in three independant parts :- Within the IMPCELPHOTOR project, we developed an experimental bench based on LBIC/ LBIV mapping, in order to visualize and identify defects within OPV device and modules.- Within the European SPrinTronics project, we worked on the improvement of OPV electrodes. For the top electrode, we selected, tested, and validated metallic inks based on silver nanoparticles compatible with inkjet printing. For the bottom electrode, we tested silver nanowires and carbon nanotubes inks to replace ITO. Satisfactory results have been obtained with an ink based on silver nanowires, which allowed us to obtain functional semi-transparent cells on glass and plastic.- Within the PHASME project, we worked on the visual aspect of a coloured OPV device. We implemented various strategies to change the color of an OPV device without altering its photovoltaic performance, the aim being to achieve full color modules. Simultaneously, we developed a colorimetric software to control and predict the color rendering on the final device (OPV plus filter).

Cellule solaire organique (OPV)

Caractérisation optique LBIC/LBIV

Électrodes semi-transparentes

Encres métalliques

Nanoparticules et nanofils d’argent

Couleur

Filtrage

Logiciel de colorimétrie

Organic solar cell (OPV)

Optical characterization LBIC/LBIV

Electrodes

Metallic inks

Color

Filter

Colorimetry software

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