Design of surface acoustic wave sensors with nanomaterial sensing layers: Application to chemical and biosensing

Sankaranarayanan, Subramanian K.R.S

01 June 2007

Surface acoustic wave (SAW) sensors detect chemical and biological species by monitoring the shifts in frequency of surface acoustic waves generated on piezoelectric substrates. Incorporation of nanomaterials having increased surface area as sensing layer have been effective in improving the sensitivity as well as miniaturization of SAW sensors. Selectivity, sensitivity and speed of response are the three primary aspects for any type of sensor. This dissertation focuses on design and development of SAW devices with novel transducer configurations employing nanomaterial sensing layers for enhanced sensing, improved selectivity, and speed of response. The sensing mechanism in these SAW sensors is a complex phenomenon involving interactions across several different length and time scales. Surface acoustic wave propagation at the macro-scale is influenced by several kinetic phenomena occurring at the molecular scale such as adsorption, diffusion, reaction, and desorption which in turn depend on the properties of nanomaterials. This suggests the requirement of a multi-scale model to effectively understand and manipulate the interactions occurring at different length scales, thereby improving sensor design. Sensor response modeling at multiple time and length scales forms part of this research, which includes perturbation theories, and simulation techniques from finite element methods to molecular-level simulations for interpreting the response of these surface acoustic wave chemical and biosensors utilizing alloy nanostructures as sensing layers. Molecular modeling of sensing layers such as transition metal alloy nanoclusters and nanowires is carried out to gain insights into their thermodynamic, structural, mechanical and dynamic properties. Finite element technique is used to understand the acoustic wave propagation at the macroscale for sensing devices operating at MHz frequencies and with novel transducer designs. The findings of this research provide insights into the design of efficient surface acoustic wave sensors. It is expected that this work will lead to a better understanding of surface acoustic wave devices with novel transducer configurations and employing nanomaterial sensing layers.

Surface acoustic wave

Nanoclusters

Nanowires

Molecular dynamics

Finite element

Acoustic streaming

American Studies

Arts and Humanities

Investigation of Nanoparticles for Use in Microwave Systems in Biomedicine

Taghavi, Houra

03 October 2013

This research focuses on the microwave properties of nanoparticles for use as contrast and hyperthermia agents. Currently, visible light is used for irradiation of nanoparticles as hyperthermia agents. Additionally, visible/Near-infrared light is used for photoacoustic tomography (PAT) imaging. Compared to optical wavelengths, frequencies in microwave range transmit through tissue with high penetration depth . Thus, deep cancerous cells and malignant tissue may be treated and imaged. These nanoparticles could enable the use of a hybrid microwave/acoustic technique known as thermoacoustic tomography. Here, quantitative measurements of the heat generation in super paramagnetic iron oxide nanoparticle (SPIONs), gold nanoparticles (AuNPs), and gold nanoclusters (AuNCs) induced by microwave energy at 3 GHz, are presented and compared. Based on our experiments, SPIONs are the most efficient nanoparticles for microwave heating. Very high concentrations of SPIONs are able to convert microwave energy into heat about 22° C more than DI-water. AuNPs, which support plasmon resonances, do not provide heat under microwave irradiation as predicted by our computational analysis based on Mie Theory. AuNCs are a new form of ultra-small (<2.5 nm) AuNPs which do not support plasmonic resonances and have supra-molecular properties such as sub-conduction band transitions. Interestingly, AuNCs have the potential to absorb microwave energy and may provide an alternative to SPIONs. These nanoparticles had not yet been studied before in this frequency region. In addition, the absorption coefficient of nanoparticles were calculated using complex permittivity data from a dip probe kit and a Vector Network Analyzer (VNA) in a broad band range from 500 MHZ to 10 GHz. This method allows identification of best frequency region with highest penetration depth. In the last step, the nanoparticles with different concentrations were tested as exogenous contrast agents in a Thermoacoustic Tomography (TAT) system. TAT utilizes the penetration depth of microwave energy while producing high resolution images through acoustic waves. The addition of an exogenous contrast agent improves image quality by more effectively converting microwave energy to heat. The experiment reveals that the time resolved thermoacoustic signal (TA) from SPIONs is stronger than AuNPs and AuNCs and thus, the image contrast produced by SPIONs is stronger than the two other aforementioned nanoparticles.

Gold nanoparticles (AuNPs)

gold nanoclusters (AuNCs)

Microwave irradiation

Novel studies on the formation and chemical reactivity of compound clusters and their precursors in the gas and liquid phase

Bradshaw, James Adam Ferguson

25 August 2008

Novel Studies on the Formation and Chemical Reactivity of Compound Clusters and Their Precursors in the Gas and Liquid Phase James A. Bradshaw 139 Pages Directed by Dr. Robert L. Whetten Presented are four separate and unique studies on molecular and nanoscale systems: Atmospheric hydration and aggregation of NaCl clusters, highly water-soluble aurous-thiolate oligomers, water-soluble gold clusters from aurous-thiolate oligomer precursors, and gold iodide clusters. Adsorption of water on cationic and anionic sodium chloride clusters is investigated to elucidate active sites of molecular interaction as well as primary aggregate formation kinetics. Considered an exceptionally abundant atmospheric species, experiments are conducted to further quantify gas phase chemistry and hydration/solvation of alkali halides. Currently the most soluble of all known gold-thiolates, para-mercaptobenzoic acid-based (pMBA) aurous-thiolate oligomers are investigated and physical and chemical properties quantified. Solubility, structural conformation, and poly-dispersity of higher homologs are observed with the goal of further applications in clusters research, medical and biomedical, and industry. Gold thiolate clusters, synthesized using pMBA-based oligomers, are investigated through reductive formation in solution. UV-VIS and UV-VIS-NIR spectroscopy is undertaken to assign structures based on predictions of the HOMO-LUMO gap and other electronic transitions. Gold iodide is investigated in relation to the common thiolate-halide analogy. Synthesis and characterization of a solid precursor as well as anion and cation cluster formation is presented as part of an ongoing collaboration.

Alkali halides

Spectroscopy

Mass spectrometry

Nanoclusters

Clusters

Nanoelectromechanical systems

Molecular structure

Nanoscience

Lacunes chargées, étude dans des nano-agrégats de silicium / Charged defects in Silicon Nanoclusters

Deb, Arpan

06 March 2012

Ce travail aborde le sujet des d efauts charg es dans le silicium. Jusqu' a pr esent, les d efauts charg es ont principalement et e etudi es en conditions p eriodiques (PBC). En e et, l'approche PBC est parfaite pour simuler unsolide in ni. Mais, comme je le montre dans ce chapitre, elle apporte aussi des artefacts. En particulier dans le traitement de l' electrostatique, o u des traitements math ematiques important doivent ^etre utilis es pour supprimer les interactions non d esir ees entre r epliques. Notre approche vise a simuler correctement un d efaut charg e, tout en conservant de bonne propri et es pourle mat eriau massif. Elle consiste a simuler le d efaut dans un nano-agr egat. Le traitement de l' electrostatique est correct dans un nano-agr egat et les r esultats obtenus peuvent ^etre extrapol es au mat eriau massif, comme il est montr e dans ce chapitre. Les perspectives de cette m ethode sont aussi abord ees ici. / In this work we have studied Si clusters with point defects in various charged states. Point defects in semiconductors affects the electronic structure of the material introducing new energy levels and consequently new modes of transport.Detailed study of the point defects have been undertaken in various approaches. The most common practice is to usesuper-cell calculations under the framework of Density Functional Theory with Periodic Boundary Conditions (PBC). Inthis formalism there are a lot of factors like defect-defect interactions, image charge interactions, that are to be correctedfor to achieve the " artefact-free" results. In this study we have used Free Boundary Conditions with nano-clusters of Sipassivated with Hydrogen at the surface. Previous works have undertaken in detail the geometrical effects in the nanoclusters. But a complete picture of the electrostatics and its effect on the energy states demand a complete study. Hence inour calculations we take another approach, devoid of the correction factors for cases with PBC, and produce an alternativeway to calculate the formation energy of the defects. We have described the formation and stability of the defects invarious charged states and provided with a detailed analysis of the properties pertaining to the nano-scale size. Finallymigration parameters are provided with respect to the charge states of the defects. Our results are also compared with thePBC calculations with critical discussions.

Nano-agrégats de silicium

Défauts chargés

Densité fonctionnelle théorie

Silicon Nanoclusters

Charged defects

Density Functional Theory

Recrystallization, abnormal grain growth and ultrafine microstructure of ODS ferritic steels / Recristallisation, croissance anormale de grains et microstructure ultra-fine des aciers ODS

Sallez, Nicolas

19 December 2014

Les alliages ODS (Oxides Dispersion Strengthened), sont principalement étudiés pour leur capacité à répondre favorablement au cahier des charges de la fonction de gainage combustible pour les réacteurs nucléaire de type RNR-Na (Réacteur à Neutrons Rapides à caloporteur sodium). Elaborés par métallurgie des poudres, mécanosynthèse puis extrusion, ils affichent des propriétés mécaniques, et notamment en fluage, extrêmement intéressantes. Néanmoins, la voie élaboration utilisée induit une forte anisotropie microstructurale. Cette anisotropie se retrouve au niveau de leurs propriétés mécaniques et conduit à une fragilité dans le sens de sollicitation transverse. Le but de cette thèse est d'étudier l'évolution microstructurale de ces matériaux. Les aciers ODS présentent des microstructures ultra fines en termes de grains, de précipités, et de formation d'amas qui conduisent à de grandes difficultés pour en obtenir la recristallisation. De plus, les microstructures obtenues présentent souvent une recristallisation avec croissance anormale. De telles évolutions demandent des investigations à très fine échelle et ont été relativement peu examinées dans le domaine des alliages ODS. Il faut en effet être capable d'une étude structurale la plus quantitative possible de la microstructure des nanograins, ainsi que de la précipitation afin d'étudier les mécanismes d'interaction précipitation / joints de grain. Ceci n'est possible que par un couplage de différentes méthodes : la microscopie électronique en transmission (en particulier avec l'utilisation des outils récemment développés pour l'étude de la nanotexturation, i.e. ACOM-TEM); la diffusion centrale des neutrons ou des rayons X; et enfin la sonde atomique tomographique, à la fois pour apporter les informations sur la morphologie et la chimie des amas et nanoprécipités mais surtout sur la composition chimique aux joints de grains. A partir de l'identification des mécanismes contrôlant la croissance anormale, une modélisation permettant de prédire son apparition dans la microstructure est confrontée à cette caractérisation microstructurale poussée. Cette modélisation prête une attention particulière à la migration des joints de grains couplée à la diffusion et effets d'ancrage préférentiel des joints triples par les précipités ainsi qu'à l'énergie motrice stockée sous forme de densité de dislocation. / Oxide Dispersion Steels (ODS) alloys are mainly studied for their ability to fulfil the technical specifications required for Sodium Fast Reactor (SFR) fuel cladding application. Their processing involves powder metallurgy, mechanical alloying and extrusion. Therefore, despite their interesting mechanical creep properties, the extrusion processing involves a high microstructural anisotropy. These particular feature leads to poor mechanical properties in the transverse direction which are worsen by the occurrence of abnormal grain growth. Unfortunately, since internal pressure increases in the tube with the accumulation of gas fission products, the major stress component is precisely applied in the transverse direction. As a result, the material faces a critical risk of failure and control of the microstructure is a key issue. The aim of this thesis is to study the microstructural evolution of ODS ferritic steels. ODS ferritic steels show ultrafine microstructures in terms both grains and precipitates which made the recrystallization very difficult and allow for abnormal grain growth. To observe such evolutions, fine scale microstructure characterization are necessary. This is only possible by coupling different characterization methods: transmission electronic microscopy (in particular with the new developed tools for nanotexturation studies, i.e. ACOM-TEM); neutron and X-ray small angle scattering; and atomic probe tomography. Based on the mechanisms that lead to and control the abnormal grain growth, a model to predict the occurrence of abnormal grain growth is confronted to the experimental results. This model that takes a particular attention to the dislocation stored energy effect to adequately reproduce the observed characterization results.

Recristallisation

Nanotexturation

Croissance anormale

Aciers

Nanodispersion d'oxydes

Recrystallization

Nanotextured material

Grain growth

Steels

Oxide nanoclusters

620

Éxcitons em nanocristais de silício / Excitons in Silicon nanocrystals

Luis Jose Borrero Gonzalez

22 October 2010

As propriedades ópticas de nanocristais de silício (Si-ncs) têm sido extensivamente estudadas após a primeira demonstração em 1990 de fotoluminescência altamente eficiente em silício poroso. Apesar dos progressos no entendimento da natureza da alta eficiência da luminescência dos Si-ncs e da enorme versatilidade para aplicações optoeletrônicas, este campo ainda é um tema de controvérsia devido à complexidade destes materiais. Além disso, as condições de preparação ainda afetam as propriedades de emissão destes materiais que são de fundamental importância para as aplicações tecnológicas. O presente trabalho teve como objetivo o estudo das propriedades óticas dos Si-ncs e entender os processos fotofisicos envolvidos na recombinação radiativa de éxcitons altamente confinados nesse sistema. Si-ncs embebidos em matriz amorfa de SiO2 foram preparados a partir de filmes de oxido de silício SiyO1-y subestequiométricos (y&ge;1/3) depositados em substratos de quartzo utilizando um sistema deposição CVD na fase estimulada por plasma (electron cyclotron resonance-plasma enhanced chemical vapor deposition ou ECR-PECVD). Esta técnica oferece boa passivação e estabilidade interfacial Si/SiO2. O tratamento térmico a altas temperaturas (900°C&le;Ta&le;1100°C) promove a precipitação do silício dentro da matriz, favorecendo um processo de nucleação e crescimento dos Si-ncs. Foram realizados tratamentos térmicos nos filmes sob atmosferas de Argônio (Ar) ou (Ar+5%H2) por duas horas. As distintas atmosferas promoveram a passivação de defeitos superficiais, principalmente de ligações pendentes pelo Hidrogênio. As propriedades associadas diretamente à fabricação, tais como estrutura cristalina, morfologia, tamanho e química da superfície dos Si-ncs foram correlacionadas com os processos de emissão envolvendo éxcitons. A caracterização estrutural foi realizada por Raio-x (XRD), Microscopia de Transmissão de Alta Resolução (HRTEM), Retroespalhamento de Rutherford e Espectroscopia Raman. As medidas óticas foram basicamente Absorção, Excitação Seletiva, Fotoluminescência CW (PL) e Fotoluminescência Resolvida no Tempo. Os resultados da caracterização indicaram que efeitos de confinamento quântico e de estados de superfície dominam o processo de recombinação no Si-nc/SiO2. Em conclusão, os resultados obtidos neste trabalho mostram uma interessante e uma nova correlação entre as condições de fabricação da amostra e os processos de recombinação de éxcitons em Si-nc/SiO2. Todos estes resultados desafiam modelos anteriores propostos para explicar as propriedades ópticas do sistema de Si-nc/SiO2 e prevê ajudar na futura aplicação tecnológica dos mesmos. / The optical properties of silicon nanocrystals (Si-nc) have been extensively studied after the first demonstration in 1990 of highly efficient photoluminescence in porous silicon. Despite progress in understanding the nature of high luminescence efficiency of Si-ncs and versatility for optoelectronic applications, this field is still a subject of controversy due to its complexity. Furthermore, the preparation conditions still affect the emission properties of these materials that are of fundamental importance for technological applications. This work aimed to study the optical properties of Si-ncs and to understand the photophysical processes involved in the radiative recombination of excitons strongly confined in this system. Si-ncs embedded in amorphous SiO2 were prepared from silicon oxide films of substoichiometric SiyO1-y (y&ge;1/3) deposited on quartz substrates using a CVD deposition system in phase stimulated by plasma (electron cyclotron resonance-plasma enhanced chemical vapor deposition ou ECR-PECVD). This technique provides good passivation and Si/SiO2 interfacial stability. The thermal treatment at high temperatures (900°C&le;Ta&le;1100°C) promotes the precipitation of silicon within the matrix, favoring a process of nucleation and growth of Si-ncs. The thermal treatments were performed in the films under Argon atmosphere (Ar) or (Ar+5%H2) for two hours. The use of different atmospheres allowed the understand of the passivation process of surface defects, particularly of dangling bonds by Hydrogen. The properties directly related to fabrication such as crystalline structure, morphology, size and surface chemistry of Si-ncs were correlated with emission processes involving excitons. The structural characterization was performed by X-Ray Diffraction (XRD), High resolution transmission electron microscopy (HRTEM), Rutherford Backscattering and Raman spectroscopy. The optical measurements were basically Absorption, Selective excitation, CW photoluminescence (PL) and Time Resolved Photoluminescence. The characterization results indicate that both quantum confinement and surface states effects dominate the recombination process in Si-ncs/SiO2. In conclusion, the results obtained in this work show an interesting and a novel correlation between the sample fabrication conditions and the exciton recombination process in Si-ncs/SiO2. All these results challenges previous models proposed to explain the optical properties of Si-nc systems and are expected to help further technological applications of this system.

Éxcitons

Fotoluminescência

Nanocristais de silício

Propriedades ópticas

Excitons

Optical properties

Photoluminescence

Silicon nanoclusters

Asymetric oxidation reactions catalyzed by chiral substituted polymers / nanoclusters; synthesis of 6-(dimethylamino)-2-phenylisoindolin-1-one derivative.

Hao, Bo

January 1900

Doctor of Philosophy / Department of Chemistry / Duy H. Hua / The discovery of new methodologies to advance the fields of synthetic organic, nanoclusters, and polymer chemistry is critical in the asymmetric synthesis of organic compounds. Particularly, catalytic asymmetric oxidation reactions are economic. The oxidation reactions provide chiral molecules and additional functionality onto the molecules for functional group manipulation. New kinds of polymers, namely chiral-substituted poly-N-vinylpyrrolidinones (CSPVPs), stabilize the bimetallic nanoclusters such as Pd/Au or Cu/Au and induce chirality. These chiral polymers wrap around the nanometer-sized (~3 nm) bimetallic nanoclusters and catalyze a number of enantioselective oxidation reactions using oxygen or hydrogen peroxide as the oxidant. Cycloalkanediols were asymmetrically oxidized by 1 atm of oxygen gas to yield the corresponding hydroxyl ketone under the catalysis of Pd/Au (3:1) – CSPVP nanoclusters. Alkenes were oxidized by Pd/Au (3:1)-CSPVP nanoclusters under 2 atmospheric of oxygen in water to give the syn-dihydroxylated products in high chemical and excellent optical yields. Various cycloalkanes underwent regio- and enantio-selective C-H oxidation with Cu/Au (3:1)-CSPVP and 30% hydrogen peroxide to produce the corresponding chiral oxo-molecules in very good to excellent chemical and optical yields. We further discovered an enantioselective desymmetrization of , -dialkenyl-alkanols and , -dialkenyl-amino acid ethyl esters to give chiral disubstituted lactones and lactams, respectively. A number of medium-sized natural products and drugs were also oxidized regioselectively to give the corresponding mono-oxygenated products. A broad-spectrum predictive C-H oxidation of complex molecules is possible. Chapter 1 mainly discussed the synthesis and characterization of the new classes of chiral substituted PVP and bimetallic nanoclusters. Chapter 2 focus on various kind of oxidation reactions by the catalysis of CSPVP stabilized bimetallic nanoclusters. Among various bioluminescence assays, firefly luciferase based bioluminescence assays are popular due to their high specific activity, low background noise and ease of use. However, it has been found that some aromatic carboxylic acid substantially inhibited the firefly luciferase reporter enzyme’s activity. In order to study firefly luciferase inhibition and the proteins associated with inhibition mechanism, we designed two 6-(dimethylamino)-2-phenylisoindolin-1-one derivatives as probe molecules. The synthesis of one probe molecule is discussed in Chapter 3 and the further investigation of its inhibitory activity on firefly luciferase is being conducted by our collaborate.

Bimetallic nanoclusters

Chiral polymer

Asymmetric oxidation

Heterogeneous Metal Catalysts: From Single Atoms to Nanoclusters and Nanoparticles

Liu, Lichen

02 October 2019

Las especies de metal con diferentes tamaños (átomos individuales, nanocristales y nanopartículas) muestran un comportamiento catalítico diferente para diversas reacciones catalíticas heterogéneas. Se ha demostrado en la bibliografía que muchos factores que incluyen el tamaño de partícula, la forma, la composición química, la interacción metal-soporte, la interacción metal-reactivo / disolvente, pueden tener influencias significativas sobre las propiedades catalíticas de los catalizadores metálicos. Los desarrollos recientes de metodologías de síntesis bien controladas y herramientas de caracterización avanzada permiten correlacionar las relaciones a nivel molecular. En esta tesis, he llevado a cabo estudios sobre catalizadores metálicos desde átomos individuales hasta nanoclusters y nanopartículas. Al desarrollar nuevas metodologías de síntesis, el tamaño de las especies metálicas puede modularse y usarse como catalizadores modelo para estudiar el efecto del tamaño sobre el comportamiento catalítico de los catalizadores metálicos para la oxidación del CO, la hidrogenación selectiva, la oxidación selectiva y la fotocatálisis. Se ha encontrado que, los átomos metálicos dispersados por separado y los grupos subnanométricos de metal pueden aglomerarse en nanoclusters o nanopartículas más grandes en condiciones de reacción. Para mejorar la estabilidad de los catalizadores subnanométricos de metal, he desarrollado una nueva estrategia para la generación de átomos individuales y clusters en zeolitas. Esas especies subnanométricas de metales son estables en tratamientos de oxidación-reducción a 550 oC. Siguiendo esta nueva metodología de síntesis, este nuevo tipo de materiales puede servir como catalizador modelo para estudiar la evolución de especies subnanométricas de metales en condiciones de reacción. La transformación estructural de las especies subnanométricas de Pt ha sido estudiada mediante microscopía electrónica de transmisión in situ. Se ha demostrado que el tamaño de las especies de Pt está fuertemente relacionado con las condiciones de reacción, que proporcionan importantes conocimientos para comprender el comportamiento de los catalizadores de metales subnanométricos en condiciones de reacción. En la otra línea de investigación para catalizadores de metales no nobles, he desarrollado varias estrategias generales para obtener catalizadores de metales no nobles, ya sea soportados sobre óxidos metálicos o protegidos por capas delgadas de carbono. Estos materiales muestran un rendimiento excelente para varias reacciones importantes, como la hidrogenación quimioselectiva de nitroarenos, incluso cuando se comparan con los catalizadores de metales nobles convencionales. En algunos casos, los catalizadores de metales no nobles pueden incluso alcanzar selectividades para productos inviables que no ha sido posible conseguir en catalizadores de metales nobles convencionales, que es causado por la diferente ruta de reacción en catalizadores de metales no nobles. Sin embargo, la espectroscopía fotoelectrónica de rayos X a presión ambiente ha revelado que la irradiación de la luz puede modular la selectividad a los alcoholes y los hidrocarburos C2 +, lo que abre una nueva posibilidad para ajustar el comportamiento catalítico de los catalizadores metálicos. Con base en los trabajos anteriores de diferentes aspectos relacionados con catalizadores metálicos heterogéneos, las perspectivas sobre las direcciones futuras hacia una mejor comprensión del comportamiento catalítico de diferentes entidades metálicas (átomos individuales, nanoagrupamientos y nanopartículas) de una manera unificadora también se han dado en esta tesis. / Les espècies metàl·liques de diferents dimensions (àtoms individuals, nanoclusters i nanopartícules) mostren diferents comportaments catalítics per a diverses reaccions catalítiques heterogènies. S'ha demostrat a la literatura que, molts factors que inclouen la mida de la partícula, la forma, la composició química, la interacció amb el suport metàl·lic, la reacció metàl·lica i la interacció amb dissolvents poden tenir influències significatives sobre les propietats catalítiques dels catalitzadors metàl·lics. Els desenvolupaments recents de metodologies de síntesi ben controlades i eines de caracterització avançada permeten relacionar les relacions a nivell molecular. En aquesta tesi, he realitzat estudis sobre catalitzadors metàl·lics d'àtoms únics a nanoclústers i nanopartícules. Mitjançant el desenvolupament de noves metodologies de síntesi, la mida de les espècies metàl·liques es pot modular i utilitzar com a catalitzadors model per estudiar l'efecte de mida sobre el comportament catalític dels catalitzadors metàl·lics per a l'oxidació de CO, hidrogenació selectiva, oxidació selectiva i fotocatàlisi. S'ha trobat que, els àtoms metàl·lics dispersos individualment i els clústers metàl·lics subnanomètrics poden aglomerar-se en nanoclústeres o nanopartícules més grans en condicions de reacció. Per millorar l'estabilitat dels catalitzadors subnanomètrics de metall, he desenvolupat una nova estratègia per a la generació d'àtoms i racimos en zeolites. Aquestes espècies metàl·liques subnanométricas són estables en tractaments de reducció d'oxidació a 550 oC. Després d'aquesta nova metodologia de síntesi, aquest nou tipus de materials poden servir com a model de catalitzador per estudiar l'evolució de les espècies metàl·liques subnanométricas en condicions de reacció. La transformació estructural de l'espècie Pn subnanométrica ha estat estudiada per microscòpia electrònica de transmissió in situ. S'ha demostrat que la mida de les espècies de Pt està fortament relacionada amb les condicions de reacció, que proporcionen idees importants per comprendre el comportament dels catalitzadors de subnanometria en condicions de reacció. En l'altra línia de recerca dels catalitzadors de metalls no nobles, he desenvolupat diverses estratègies generals per obtenir catalizadors de metalls no nobles recolzats en òxids metàl·lics o protegits per capes de carboni primes. Aquests materials presenten un excel·lent rendiment per a diverses reaccions importants, com la hidrogenació quimioelectiva de nitroarenes, fins i tot quan es comparen amb els catalitzadors convencionals de metall noble. En alguns casos, els catalitzadors de metalls no nobles poden fins i tot aconseguir selectivitats a productes no factibles que no s'han pogut assolir en catalitzadors de metall noble convencionals, que es deuen a la via de reacció diferent en catalitzadors de metalls no nobles. No obstant això, s'ha observat una espectroscòpia de fotoelèctria de raigs X amb pressió d'atmosfera que la irradiació lleugera pot modular la selectivitat als alcohols i hidrocarburs C2 +, la qual cosa obre una nova possibilitat per sintonitzar el comportament catalític dels catalitzadors metàl·lics. A partir d'aquests treballs de diferents aspectes relacionats amb els catalitzadors metàl·lics heterogenis, també s'ha donat en aquesta tesi perspectives sobre les futures orientacions cap a una millor comprensió del comportament catalític de diferents entitats metàl·liques (àtoms individuals, nanoclústers i nanopartícules). / Metal species with different size (single atoms, nanoclusters and nanoparticles) show different catalytic behavior for various heterogeneous catalytic reactions. It has been shown in the literature that, many factors including the particle size, shape, chemical composition, metal-support interaction, metal-reactant/solvent interaction, can have significant influences on the catalytic properties of metal catalysts. The recent developments of well-controlled synthesis methodologies and advanced characterization tools allow to correlate the relationships at molecular level. In this thesis, I have carried out studies on metal catalysts from single atoms to nanoclusters and nanoparticles. By developing new synthesis methodologies, the size of metal species can be modulated and used as model catalysts to study the size effect on the catalytic behavior of metal catalysts for CO oxidation, selective hydrogenation, selective oxidation and photocatalysis. It has been found that, singly dispersed metal atoms and subnanometric metal clusters may agglomerate into larger nanoclusters or nanoparticles under reaction conditions. To improve the stability of subnanometric metal catalysts, I have developed a new strategy for the generation of single atoms and clusters in zeolites. Those subnanometric metal species are stable in oxidation-reduction treatments at 550 oC. Following this new synthesis methodology, this new type of materials can serve as model catalyst to study the evolution of subnanometric metal species under reaction conditions. The structural transformation of subnanometric Pt species has been studied by in situ transmission electron microscopy. It has been shown that the size of Pt species is strongly related with the reaction conditions, which provide important insights for understanding the behavior of subnanometric metal catalysts under reaction conditions. In the other research line for non-noble metal catalysts, I have developed several general strategies to obtain non-noble metal catalysts either supported on metal oxides or protected by thin carbon layers. These materials show excellent performance for several important reactions, such as chemoselective hydrogenation of nitroarenes, even when compared with conventional noble metal catalysts. In some cases, non-noble metal catalysts can even achieve selectivities to unfeasible products which has not been possible to achieve on conventional noble metal catalysts, which is caused by the different reaction pathway on non-noble metal catalysts. Nevertheless, it has been revealed by ambient-pressure X-ray photoelectron spectroscopy that light irradiation can modulate the selectivity to alcohols and C2+ hydrocarbons, which opens a new possibility for tuning the catalytic behavior of metal catalysts. Based on the above works from different aspects related with heterogeneous metal catalysts, perspectives on the future directions towards better understanding on the catalytic behavior of different metal entities (single atoms, nanoclusters and nanoparticles) in a unifying manner have also been given in this thesis. / Liu, L. (2018). Heterogeneous Metal Catalysts: From Single Atoms to Nanoclusters and Nanoparticles [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/113169 / TESIS

Single atoms

Nanoclusters

Nanoparticles

Zeolite

Selective oxidation

Selective Hydrogenation

Photocatalysis

In situ Characterizations

QUIMICA ORGANICA

Atomically Precise Silver Nanoclusters: Controlled Synthesis and Assembly into Structurally Diverse Frameworks with Tailored Optical Properties

Alhilaly, Mohammad Jaber

24 October 2019

Ligand-protected metal nanoclusters (NCs), which are ultra-small nanoparticles marked by their atomic precision, are distinctly importance for contemporary nanomaterials. NCs have attracted significant research attention for utilizing their novel optical and physicochemical properties in various applications, including fluorescence sensing, catalysis, and biomedical applications. This dissertation deals with ligand-protected atomically precise silver NCs and is divided into two main parts. The first part is focused on the exploration and design of well-defined silver NCs through surface co-ligand engineering. The second part is related to the development of silver NC-based frameworks (NCFs). In the first part, we designed a synthetic strategy based on engineering the structure of the phosphine co-ligands with thiols to generate the large box-shaped [Ag67(SPhMe2)32(PPh3)8]3+ (referred to as Ag67) NC. The strategy demonstrates that the combined use of judiciously chosen thiol and phosphine co-ligands can result in stable highly anisotropic box-like shapes. The optical absorption spectrum of the Ag67 NC displays highly structured multiple sharp peaks. The crystal structure shows a Ag23 core formed of a centered cuboctahedron (an unprecedented core geometry in silver clusters), which is encased by a layer with a composition of Ag44S32P8 arranged in the shape of a box. The electronic structure of this box-shaped cluster resembles a jellium box model with 32 free electrons. In the second part, a novel approach is developed for the assembly and linkage of atomically precise Ag NCs into one-dimensional (1D) and two-dimensional (2D) NC-based frameworks (NCFs) with atomic-level control over cluster size and dimensionality. With this approach three novel, but related, crystal structures (one silver NC and two NCFs) were synthesized. These structures have the same protecting ligands, and also the same organic linker. The three structures exhibit a similar square gyrobicupola geometry of the building NC unit with only a single Ag atom difference. The critical role of using a chloride template in controlling the NC’s nuclearity was demonstrated, as well as the effect of a single Ag atom difference in the NC’s size on the NCF’s dimensionality, optical properties, and thermal stability.

ligand-protected

atomically precise

nanoclusters

Metal-organic framework

X-ray crystallography

Příprava nanokompozitů oxidu kovů v plazmovém polymeru a studium jejich vlastností / Preparation of Nanocomposites of Metal Oxides in Plasma Polymer and Study of Their Properties

Polonskyi, Oleksandr

January 2012

Title: Preparation of Nanocomposites of Metal Oxides in Plasma Polymer and Study of Their Properties Author: Oleksandr Polonskyi Department: Department of Macromolecular Physics, MFF UK Supervisor of the doctoral thesis: Prof. RNDr. Hynek Biederman, DrSc. Department of Macromolecular Physics, Faculty of Mathematics and Physics, Charles University in Prague Abstract: This thesis is devoted to a study of nanocomposite films Al (Al oxide)/plasma polymer prepared by various techniques using magnetron sputtering, plasma polymerization and cluster beam deposition. The formation and deposition of metal/metal oxide nanoclusters using a gas aggregation cluster source (GAS) was also considered. The role of low concentration of oxygen in the aggregation gas on the process of Al and Ti cluster deposition was studied. Properties of the nanoclusters and nanocomposite films were characterized by various techniques. Morphology of the nanocomposites was examined by AFM, TEM or HRTEM and SEM. Elemental analysis and chemical composition of the films were studied by XPS and FTIR. Optical characterization of the prepared films was done by UV-Vis spectroscopy and spectroscopic ellipsometry. It has been shown that using GAS nanocomposite Al(AlxOy)/C:H may be prepared. Keywords: nanocomposite thin film, plasma polymer, metal...