Global ETD Search

11	Resolving the molecular mechanisms of inherited deafness caused by missense mutations in cadherin 23. Thornburg, Adrienne 28 September 2016 (has links) No description available. Biophysics Biochemistry cadherin X-ray crystallography Differential scanning dluorimetry
12	Melt transformation coextrusion of polypropylene and polyethylene Shoemaker, Craig L. January 1984 (has links) No description available. Engineering, Chemical Melt Transformation Coextrusion Differential Scanning Calorimetry Polyethylene
13	The Development of High-Throughput and Miniaturized Differential Scanning Calorimeter for Thermodynamic Study of Bio-Molecules Yu, Shifeng 19 February 2019 (has links) Biomolecular interactions are fundamentally important for a wide variety of biological processes. Understanding the temperature dependence of biomolecular interactions is hence critical for applications in fundamental sciences and drug discovery. Micro-Electro-Mechanical Systems (MEMS) technology holds great potential in facilitating temperature-dependent characterization of biomolecular interactions by providing on-chip microfluidic handling with drastically reduced sample consumption, and well controlled micro- or nanoscale environments in which biomolecules are effectively and efficiently manipulated and analyzed. This dissertation is focused on a high-through and miniaturized differential scanning calorimeter for thermodynamic study of bio-molecules using MEMS techniques. The dissertation firstly introduces the overall design and operation principles. This miniaturized DSC was fabricated based on a polyimide (PI) thin film. Highly temperature sensitive vanadium oxide was used as the thermistor material. A PDMS (Polydimethylsiloxane) microfluidic chamber was separately fabricated and then bonded firmly with the PI substrate by a stamp-and-stick method. Meanwhile, the micro heater design was optimized to reach better uniformity. A heating stage was constructed for fast and reliable scanning. In this study, we used syringes to deliver the 0.63 μL liquid sample into both the sample and reference chambers. All the testing processes were functionalized using the LabVIEW programs. The sensing material was also characterized. To seek a higher temperature coefficient of resistance (TCR) and less resistive behavior, explorations about various PVD (physical vapor deposition) parameters and annealing conditions were conducted for optimization. In this research, we found vanadium oxide deposited under certain conditions leads to the highest TCR value (a maximum of 2.51%/oC). To better understand the material’s property, we also did the XRD (X-ray Diffraction), SEM (Scanning electron microscope). The micro calorimeter was calibrated using a step thermal response. The time constant was around 3s, the thermal conductance was 0.6mW/K, and the sensitivity was 6.1V/W. The static power resolution of the device at equilibrium is 100 nW, corresponding to 250 nJ/K. These performances confirmed the design and material to be appropriate for both good thermal isolation and power sensitivity. We demonstrated the miniaturized DSC’s performance on several different kinds of protein samples: lysozyme, and mAb (monoclonal antibody) and a DVD IgG (double variable domain immunoglobulin G). The results were found to be reasonable by comparing it with the commercial DSC’s tests. Finally, this instrument may be ideal for incorporation into high throughput screening workflows for the relative comparison of thermal properties between large numbers of proteins when only small quantities are available. The micro-DSC has the potential to characterize the thermal stability of the protein sample with significantly higher throughput and less sample consumption, which could potentially reduce the time and cost for the drug formulation in the pharmaceutical industry. / Ph. D. / Virtually all biological phenomena depend on molecular interactions, which is either intra-molecular as protein folding/unfolding or intermolecular as in ligand binding. A basic biology problem is to understand the folding and denaturation processes of a protein: the kinetics, thermodynamics and how a protein unfolds and folds back into its native state. Both folding/unfolding and denaturation processes are associated with enthalpy changes. The thermodynamics of binding compounds helps a great deal to understand the nature and potency of such molecules and is essential in drug discovery. As a label-free and immobilization-free method, calorimetry can evaluate the Gibbs free energy, enthalpy, entropy, specific heat, and stoichiometry, and thus provides a fundamental understanding of the molecular interactions. Calorimetric systems including isothermal titration calorimeters (ITC) and differential scanning calorimeters (DSC) are the gold standard for characterizing molecular interactions. In this research, a micro DSC is developed for direct thermodynamic study of bio-molecules. Compared with the current commercial DSC, it is on a much smaller scale. It consumes much less sample and time in each DSC measurement. It can enable comprehensive high-content thermodynamics study in the early stage of drug discovery and formulation. It also enables direct, precise, and rapid evaluation of the folding and unfolding of the large biomolecules like proteins, DNAs, and enzymes without labeling or immobilization. It can also be used as a powerful tool to study the membrane proteins, which is often impractical or impossible before. MEMS Differential Scanning Calorimeter Thermodynamic Protein Stability Transition Temperature
14	Thermisch härtende Polymerverbundmaterialien als Basis für neue Befestigungssysteme / Thermally curable polymeric composit material as a basis for new chemical fixing systems Pöhlmann, Milena 07 December 2006 (has links) (PDF) Mit der Entwicklung und Einführung ökologischer Bauweise im Neubau sowie neuen Baustoffsystemen in Sandwichbauweise wird es zunehmend erforderlich, neue effektive Befestigungsvarianten zu entwickeln, die eine dauerhafte Fixierung auch unter sicherheitstechnischen Bestimmungen sowie aus Garantie- bzw. haftungsrechtlichen Gründen ermöglichen. Die aus der Praxis bisher bekannten chemischen Befestigungssysteme (Zweikomponentenverbundmörtel, Verbundankerpatronen) weisen hinsichtlich der Applikation unter bautechnischen Bedingungen noch einige Nachteile auf. Dazu gehören vor allem längere Aushärtungszeiten zur Realisierung der abschließenden Verbundfestigkeit, Inhomogenitäten im Verbund, der Einsatz toxischer Verbindungen und eine Limitierung der Applikationsmöglichkeiten in horizontalen und Überkopf-Einsatzbereichen sowie Hohlkammersystemen. Alle zuvor genannten Punkte haben bis jetzt die Nutzung solcher Verbundwerkstoffe als universale Anwendungsmöglichkeit verhindert. Ein neues chemisches Befestigungssystem, welches aus Novolak gehärteten mit Hexamethylentetramin (Hexa) und anorganischen Füllstoff besteht, wurde für Applikationen in Beton entwickelt. Das Bindemittel härtet bei der Temperaturzuführung aus. Die unkatalysierte Befestigungsmasse zeigt bei einer Temperatur zwischen 150-300 °C eine hohe Reaktivität. Die Vorteile dieses Systems sind die unbegrenzte Lagerfähigkeit der vorgemischten härtbaren Masse sowie die Gewährleistung einer homogenen Netzwerkstruktur im gesamten Verbund und sie ist frei von giftigen und flüchtigen Substanzen. Auf den Einsatz toxischer Substanzen wurde verzichtet. In dieser Arbeit wurde die Gesamtkinetik der Reaktion während des Aushärtungsprozesses dieser Polymerkomposite untersucht. Die DSC- (nicht-isothermen, isothermen) und MDSC-Untersuchungen haben sich als ein sicheres Verfahren zur Qualitätskontrolle des Aushärtezustands der Befestigungssysteme herausgestellt. Parallel zur nicht-isothermischen und isothermischen DSC wurden Leitfähigkeitsmessungen durchgeführt, um den Endpunkt der Aushärtungsreaktion zu bestimmen. / The development and introduction of ecological construction methods and the use of sandwich materials make it necessary to develop new fixing systems and technologies. Dealing with the application in concrete and other substrates commercial chemical fixing systems show some disadvantages up to date. Especially the rather long curing time in order to realize the final bond strength, inhomogenities in the composite, the partial use of toxic substances and application limits of such systems in horizontal direction as well as hollow section materials has so far prevented the use of such composites for all-purpose applications. A new chemical fixing system, which consists of hexamethylene tetramine (hexa) cured novolac and inorganic filler, was developed for application in concrete. It is applied by a thermo-curing procedure. The uncatalyzed curable mixture has a high reactivity at temperature between 150-300 °C. Compared with commercial chemical fixing systems, the premixed curable mass has many benefits. First it has a unique storage stability and second, it is free of toxic and volatile substances. Another important aspect is, it is self-foaming. In this study was investigated the overall kinetics of the reaction during the curing process of these polymer composites. An appropriate method for this experiment proved to be the DSC in isothermal and non-isothermal mode and MDSC. This turned out to be a safe quality control technique for these systems. Parallel to the non-isothermal and isothermal DSC conductivity measurements have been performed to determine the end point of the curing reaction. Befestigungssysteme Härtung Novolak Hexamethylentetramin (Hexa) Differential Scanning Calorimetry (DSC) MDSC Zugversuche polymeric composit material curing Novolac hexamethylene tetramine (Hexa) Differential Scanning Calorimetry (DSC) MDSC pull-out test ddc:620 rvk:ZI 3430 Verbundverhalten Haftvermittler Sandwichbauweise Hexamethylentetramin Differential scanning calorimetry
15	Värmebehandling av segjärn med hög kiselhalt / Heat treatment of ductile iron with high silicon content Zander, Patrik, Hammarström, Johan January 2011 (has links) Bakgrunden till detta examensarbete var att Qumex Materialteknik vid ett flertal tillfällen konstaterat att material av typen SS 0725 har uppvisat bristfälliga härdresultat. Materialet, som är relativt nytt på marknaden, är ett gjutjärn av typen segjärn och utmärker sig gentemot andra segjärn på grund av sitt höga innehåll av kisel. Då segjärn enligt den nu gällande EN-standarden klassificeras efter sina mekaniska egenskaper uppstår ett problem gällande SS 0725. Materialet uppfyller de krav som är ställda för EN-GJS-500-7 och hamnar därmed under samma materialbeteckning som ett segjärn med betydligt lägre kiselhalt. Att två material med olika kemisk sammansättning hamnar under samma beteckning kan innebära problem. Syftet med denna rapport är att fastslå vilken påverkan den höga kiselhalten har på materialet vid värmebehandling av typen släckhärdning med efterföljande anlöpning. I försöken ingick fyra material. Det som skiljde materialen åt var halterna av koppar och kisel. De härdades vid tre olika temperaturer och under tre olika tider för att sedan släckas i olja. Målet med släckhärdningen var att materialen skulle få en helt martensitisk struktur vilket då klassades som ett bra härdresultat. Resultatet utvärderades sedan genom optisk mikroskopi och hårdhetsmätningar. En undersökning av materialens fasomvandlingstemperaturer genomfördes med hjälp av Differential Scanning Calorimetry. Resultatet visar att kiselhalten har stor påverkan på den temperatur som krävs för att erhålla ett bra härdresultat. För material med låg kiselhalt uppnåddes fullständig martensitbildning efter släckhärdning från 840°C. För material med hög kiselhalt uppnåddes liknande strukturella och hårdhetsmässiga resultat först vid en så hög temperatur som 900°C och behandlingstider längre än 1 h. Den relativa skillnad som uppmättes i fasomvandlingstemperatur med hjälp av Differential Scanning Calorimetry mellan högkiselmaterial och lågkiselmaterial var 45°C. Detta resultat kombinerat med analyserna av härdprocesserna visar att det krävs kraftigt ökad temperatur vid värmebehandling av högkiselmaterialet SS 0725. / The background to this thesis was that Qumex Materialteknik at several occasions had received material of type SS 0725 that had shown deficient heat treatment results. The material, which is relatively new, is a cast iron of type ductile iron and differ against other ductile irons because of its high silicon content. According to EN standard ductile irons are classified by their mechanical properties. A problem then occurs with the new material SS 0725 because of this. The material fulfils the requirements for EN-GJS-500-7 and is therefore in the same classification as a ductile iron with much lower silicon content. Two materials having major differences in chemical composition ending up in the same classification can be problematic. The purpose of this report is to determine impact of high silicon content in ductile iron when heat treated and quench hardened. The experiment included four materials, and the major difference between the materials were their content of copper and silicon. The heat treatment process was performed at three different temperatures and three different treatment times. Afterwards the samples were quenched in oil. The ambition of the quench hardening was to obtain a material structure of 100% martensite. By optical microscopy and hardness measurements the results then were evaluated. An investigation of the phase transformation temperature in the materials was made by using Differential Scanning Calorimetry. The results show that the amount of silicon content has great influence on the temperature for receiving good hardening results. To achieve 100% martensite after quench hardening in materials with low silicon content the temperature needs to be over 840°C. For material with high level of silicon content the temperature for achieving 100% martensite needs to be 900°C and the treatment time should be over 1 h. The relative difference in phase transformation temperature was measured using Differential Scanning Calorimetry. The results of the measurements between the materials with high silicon content and materials with low silicon content was 45°C. This result combined with the analysis of the heat treatment process shows that a major increase of the temperature is needed to heat treat SS 0725. Cast iron Ductile iron Heat treatment Quench hardening Silicon DSC - Differential Scanning Calorimetry Gjutjärn Segjärn Värmebehandling Släckhärdning Kisel DSC - Differential Scanning Calorimetry
16	Synthesis and sorption studies of porous metal-organic hosts Batisai, Eustina 03 1900 (has links) Thesis (PhD)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The first part of this study describes the synthesis of new porous materials from basic building blocks. Five structurally related ligands namely: N,N'-bis(3-pyridylmethyl)-naphthalene diimide (L1), N,N'-bis(4-pyridylmethyl)-naphthalene diimide (L2), N,N'-bis(4-pyridylmethyl)- pyromellitic diimide (L3), N,N'-bis(3-pyridylmethyl)-pyromellitic diimide (L4) and 2-(pyridin-4- ylmethyl)-benzene tricarboxylic anhydride (L5) were synthesised. Ligands L1 and L2 were reacted with metal nitrates and carboxylates as co-ligands in a systematic manner with a view to obtaining potentially porous 3–D coordination polymers. Ten structurally diverse coordination polymers were obtained and they were characterised by single-crystal X-ray diffraction, powder X-ray diffraction and thermogravimetric analysis. Four of these compounds absorb moderate amounts of CO2 and, in addition, show sorption selectivity towards CO2 over N2. The reaction of L3 and L4 with transition metal halides yielded two 1–D chains, while the reaction of L5 with transition metal nitrates yielded seven coordination polymers of which four are 2–D and three are 1–D. Of the 2–D structures three are isostructural. The second part of this work describes a variable pressure study of a flexible metal-organic framework [Zn2(BDC)2(BPY)] (BPY = 4,4 -bipyridine and BDC = 1,4-benzene dicarboxylic acid). [Zn2(BDC)2(BPY)] is one of the few examples of a flexible metal-organic framework that undergoes phase transformations in response to gas pressure. The high pressure sorption recorded for this metal-organic framework displays two inflection steps in the pressure range 0 to 30 bar, possibly indicating two phase transformations. The gas-loaded structures for each phase transformation were determined by means of single-crystal X-ray diffraction. High-pressure differential scanning calorimetry was also carried out on the system in order to determine accurate gate-opening pressures, as well as the energies involved with each phase transformation. The results correlate with those obtained from single-crystal X-ray diffraction and high-pressure sorption. The final section reports the mechanochemical synthesis of two Werner complexes [NiCl2(4- PhPy)4] (1), [CoCl2(4-PhPy)4] (2) and their corresponding solid solution [Ni0.5Co0.5Cl2(4-PhPy)4] (3) (PhPy = phenyl pyridine). The solid solution could only be formed by mechanochemical synthesis and not by conventional solution crystallisation methods. The solid solution exhibits sorption properties that differ from those of the pure compounds. / AFRIKAANSE OPSOMMING: Die eerste deel van hierdie studie beskryf die sintese van nuwe poreuse stowwe uit basiese boublokke. Vyf struktureel verwante ligande naamlik: N,N'-bis(3-piridielmetiel)-naftaleen diimied (L1), N,N'-bis(4-piridielmetiel)-naftaleen diimied (L2), N,N'-bis(4-piridielmetiel)- piromellitien diimied (L3), N,N'-bis(3-piridielmetiel)-piromellitien diimied (L4) en 2-(piridiel-4- ielmetiel)benseen trianhidried (L5) is gesintetiseer. Ligande L1 en L2 is gereageer met metaal nitrate en karboksielsure as mede-ligande in 'n sistematiese wyse met 'n oog op die verkryging van potensieel poreuse 3–D koördinasie polimere. Tien struktureel diverse koördinasie polimere is verkry en hulle is gekarakteriseer deur enkel-kristal X-straal-diffraksie, poeier X-straal diffraksie en termo-analise (thermal analysis). Vier van hierdie verbindings het matige hoeveelhede CO2 geabsorbeer en, bykomend, wys sorpsie selektiwiteit van CO2 oor N2. Die reaksie van L3 en L4 met oorgangsmetaalhaliede het twee 1–D kettings gevorm, terwyl die reaksie van L5 met oorgangsmetaal nitrate sewe koördinasie polimere opgelewer het, waarvan vier 2–D en drie 1–D polimere is. Van die 2–D polimere het drie vergelykbare strukture. Die tweede deel van hierdie werk beskryf 'n veranderlike druk studie van 'n buigsame metaalorganiese raamwerk [Zn2(BDC)2(BPY)] (BPY = 4,4-bipiridien en BDC = 1,4-benseen dikarboksielsuur). [Zn2(BDC)2(BPY)] is een van die min voorbeelde van 'n buigsame metaalorganiese raamwerk wat fase transformasies (phase transformations) ondergaan in respons op ‘n verandering in gas druk. Die hoë-druk sorpsie aangeteken vir hierdie metaal-organiese raamwerk vertoon twee infleksie stappe in die gebestudeerde druk gebied (0 tot 30 bar), wat moontlik op twee fase transformasies dui. Die gas-gelaaide strukture vir elke fase transformasie is bepaal deur middel van enkel-kristal X-straal-diffraksie. Hoë-druk differensiële skandeer kalorimetrie (differential scanning calorimetry) is ook uitgevoer op die stelsel ten einde dié akkurate hekopenings druk, sowel as die energie betrokke by elke fase transformasie te bepaal. Die resultate stem ooreen met dié verkry vanaf enkel-kristal X-straal diffraksie en hoë-druk sorpsie. Die finale afdeling bespreek die meganochemiese sintese van twee Werner komplekse [NiCl2(4-PhPy)4] (1) en [COCl2(4-PhPy)4] (2) en hul ooreenstemmende vaste oplossing (solid solution) [Ni0.5Co0.5Cl2(4-PhPy)4] (3). Die vaste oplossing kan slegs gevorm word deur meganochemiese sintese en nie deur konvensionele oplossing kristallisasie metodes. Die vaste oplossing vertoon sorpsie eienskappe wat verskil van dié van die suiwer verbindings. Crystal engineering Metal-organic frameworks Werner clathrates Porous materials UCTD
17	Imperfections in Recycled Aluminium-Silicon Cast Alloys Bjurenstedt, Anton January 2015 (has links) In striving to produce high quality cast components from recycled aluminium alloys,imperfections have to be considered, because recycled aluminium usually containsmore of it. However, there are great energy savings to be made by using recycledaluminium; as little as 5% of the energy needed for primary aluminium productionmay be required. High quality castings are dependent on, besides alloy chemistry, bothmelt quality and the casting process; the focus of this work is related to the meltquality.This thesis aims to increase knowledge about imperfections, foremost about Fe-richparticles, oxides/bifilms, and porosity. Experiments were performed at industrialfoundry facilities and in a laboratory environment. Melt quality was evaluated byproducing samples with the reduced pressure test (RPT), from which both densityindex (DI) and bifilm index (BI) could be measured, results that were related to tensiletest properties. Data from tensile test samples were analysed, and fracture surfacesand cross sections were studied in both light microscope and in scanning electronmicroscope (SEM). For the purpose of investigating nucleation of primary Fe-richparticles (sludge) differential scanning calorimetry (DSC) was used.In the analysis of results, a correlation between the morphology of particles and tensileproperties were found. And elongated Fe-rich β-particles were seen to fracturethrough cleavage towards the centre. However, DI and BI have not been possible torelate to tensile properties.The nucleation temperature of primary Fe-rich particles were found to increase withincreased Fe, Mn, and Cr contents, i.e. the sludge factor (SF), regardless of cooling rate.For a set SF, an increase of cooling rate will decrease the nucleation temperature. Imperfections Recycled cast Al-Si alloy Fe-rich particles Melt quality Fractography Differential scanning calorimetry.
18	Preformulation and formulation study of dexchlorphenniramine maleate for use in the development of a new sustained release dosage form Fabian, June 03 1900 (has links) A Dissertation Submitted to the Faculty of Medicine, University of the Witwatersrand, Johannesburg, in Partial Fulfilment of the Requirements for the Degree of Master of Pharmacy Johannesburg, March 1994 / Preformulation and formulation study of dexchlor- pheniramine maleate (DCPM) for it's inclusion into a gelforming sustained release dosage form was investigated. A modification of the USP apparatus 2 is proposed as an alternative to currently recommended USP dissolution apparatus for floating, gelforming drug delivery systems. In addition, the role of magnesium stearate and talc as dissolution retardants in controlled release matrix tablets is investigated, through application of a factorial design. / IT2018 dexchlorpheniramine Calorimetry, Differential Scanning Chromatography Chromatography, High Pressure Liquid Spectrophotometry, Ultraviolet
19	Tratamento térmico pré e pós-cura de diferentes compósitos: análise térmica, reistência à flexão e grau de conversão / Heat treatment pre and post cured of differents composites: thermal analysis, flexural strength and degree of conversion Gomes, Mauricio Neves 04 June 2008 (has links) O objetivo deste estudo é realizar a caracterização térmica, resistência à flexão e o grau de conversão de um compósito nanoparticulado (Filtek Supreme XT: FT) e um microhíbrido (Esthet X: ET), cor A2, submetidos a diferentes tratamentos térmicos. Os grupos experimentais foram: G1: sem tratamento; G2: pré-aquecimento à 68°C com dispositivo Calset; G3: pós-aquecimento em forno MP-130, 10°C/min até 140°C e G4: pré e pós-aquecimento. Depois da fotoativação, foram realizadas análise termogravimétrica e calorimetria exploratória diferencial (DSC) para determinar a estabilidade térmica dos compósitos, temperatura de transição vítrea (Tg), pico de exotermia e calor liberado após fotoativação. O ensaio de resistência à flexão foi realizado 24h após armazenagem dos corpos de prova em água destilada a 37°C. A análise do grau de conversão foi realizada com espectrofotômetro FT-Raman. Análise de variância e teste de Tukey (p<0,05) demonstraram que os compósitos FT e ET têm 25,8% e 23,7% de matriz orgânica em peso respectivamente e estabilidade térmica até 200°C. O pico exotérmico do G2 (63,5°C) é maior do que G1 (60,9°C). Os grupos G3 e G4 não apresentaram pico exotérmico e calor liberado. A tg é de aproximadamente 160,5°C para o FT e de 161,4°C para o ET. A resistência à flexão (MPa) e grau de conversão(%) foram respectivamente: G1 (149,1; 60)=G2(152,5; 56,4) e G3 (170,5; 72,6)=G4 (178,2; 71,8) . O compósito ET apresenta maior grau de conversão que FT. À partir da caracterização térmica foi possível observar que o pré-aquecimento em condições não isotérmicas não promoveu maior conversão e resistência à flexão. O tratamento térmico deve ser realizado acima de 160°C. / The aim of this study was to perform the thermal characterization,flexural strength and degree of conversion of two composites, a nanofilled (Filtek Supreme XT: FT) and a microhybrid (Esthet X: ET), shade A2, submitted to different thermal treatments. Methods: The experimental groups were: G1: no treatment; G2: preheated at 68°C with Calset device; G3: post-heated in a MP-130 (EDG) oven, 10 °C/min up to reach 140°C for 20min and G4: pre and post-heated. After curing, thermogravimetric analysis and differential scanning calorimetry (DSC) were carried to determine thermal stability of the composites, glass transition temperature (Tg), exothermic peak and heat releasing after photoactivation. Three-point flexural test was performed after stored in water at 37oC for 24 hours. Degree of conversion was determined using a spectrophotometer FT-Raman. Analysis of variance and Tukey\'s test (P<0.05) showed that FT and ET composites have 25.8% and 23.7% of organic matrix in weight respectively and thermal stability at 200°C. The G2 group release more heat (9.9J/g) than G1 (7.3J/g). Exothermic peak of G2 group (63.5°C) is higher than G1 (60.9°C). G3 and G4 groups did not show exothermic peak and heat releasing. ET composite of G2 group presented the highest exothermic peak (65.2°C) of all groups. The Tg is nearly 160.5°C to FT and 161.4°C to ET. Flexural strength (MPa) and degree of conversion (%) were respectively: G1(149.1; 60) = G2(152.5; 56.4) and G3 (170.5; 72.6) = G4 (178,2; 71,8). ET composite presented higher conversion values than FT. Pre-heating at non-isothermal conditions does not promote higher conversion and flexural strength. Heat treatment after cure can be carried through 160°C. Composite resins Materials Resistance Resinas compostas Resistência de materiais
20	Investigating Thermal Transformations of Ligand-Stabilized Gold Nanoparticles: Influence of the Structural Attributes of the Nanoparticle and Its Environment on Thermal Stability Smith, Beverly 18 August 2015 (has links) Ligand-stabilized metal nanoparticles (LSNPs) have garnered significant attention for use in applications including sensing, catalysis, and thin film fabrication. Many uses rely on the size-dependent properties of the metal nanoparticle core. Therefore, preservation of nanoparticle core size is of paramount importance. In other uses, the low processing temperatures afforded by metal LSNPs make them attractive as precursors for conductive thin films. In these distinctly different applications, understanding nanoparticle thermal stability is crucial. A key finding of this research is that nanoparticle sintering is dependent upon both core size and ligand functionality. Multi-technique analysis of four types of gold nanoparticles (AuNPs) with different ligand compositions and core sizes illustrates that more volatile ligands reduce the onset temperature for sintering. Also, AuNPs of larger core size with the same ligand composition exhibit lower sintering onset temperatures. Correlation between measurements reveals that only a small amount of ligand loss is necessary to trigger rapid sintering and that ligands are excluded to the surface of the porous gold films. AuNPs with ligand shells composed of two alkanethiols of different chain length and volatility indicate that the onset temperature of sintering can be tuned further through incorporation of a small amount of more volatile alkanethiol into a ligand shell of lower volatility. Mixed LSNPs further reveal that AuNP thermal stability depends upon the ligand shell composition and its intermolecular interactions, which can result in markedly different sintering behavior for different ligand compositions. Long-chain alkanethiol AuNPs sinter after only a small amount of ligand loss, whereas short-chain alkanethiol AuNPs sinter following complete ligand loss and the formation of metastable bare AuNPs. Heated AuNP films prepared with mixed-ligand AuNPs exhibit ligand-dependent differences in film morphology. To probe AuNP thermal stability in 2D-assemblies, self-assembly using larger ‘marker’ nanoparticles enables the study of small 1.5 nm AuNP arrays with successive TEM monitoring throughout ex situ heating. Monitoring images of the same area shows short-range (1-2 nm) nanoparticle migration/coalescence. In contrast to 3D assemblies, AuNP growth occurs at temperatures as low as 60 °C. This dissertation includes previously published and unpublished co-authored material. / 10000-01-01 Differential scanning calorimetry Gold nanoparticles Ligand-stabilized nanoparticles Nanoparticle sintering Nanoparticle transformations Thermogravimetric analysis

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