Global ETD Search

641	Untersuchungen von neuartigen Platinkatalysatoren, präpariert unter Nutzung des Biotemplatings, mit miniaturisierten kalorimetrischen Anordnungen Ullrich, Frank 28 March 2008 (has links) Durch Biotemplating mit bakteriellen Oberflächenproteinen, sogenannten S-Layer Proteinen können Metallcluster mit einer definierten Größe und Verteilung auf verschiedensten Oberflächen abgeschieden werden. Damit eröffnet sich die Möglichkeit der gezielten Präparation heterogener Katalysatoren. Mit der Kalorimetrie sollen die katalytischen Eigenschaften von mit Platin belegten S-Layer Präparationen am Beispiel der Kohlenmonoxidoxidation vorgestellt werden. Es werden geträgerte Katalysatoren und katalytisch aktive Schichten untersucht. Der Fokus liegt bei den Katalysatorschüttungen auf der Charakterisierung der katalytischen Eigenschaften und resultierend daraus auf einer Optimierung der Präparation. Für die Untersuchungen der katalytisch aktiven Schichten muss im Unterschied zu den Katalysatorschüttungen eine neuartige miniaturisierte Anordnung auf der Basis von Pt 1000 Widerstandsthermometern entwickelt werden. Dabei werden auch Parameter, die für eine spätere sensorische Applikation von Bedeutung sind, untersucht. info:eu-repo/classification/ddc/540 ddc:540
642	Physikalisch-chemische Charakterisierung von ausgewählten supramolekularen Kristalleinschlussverbindungen Sumarna, Omay 23 September 2002 (has links) Die vorliegende Arbeit befasst sich mit experimentellen Untersuchungen zur physikalisch-chemischen und strukturellen Charakterisierung von neuartigen supramolekularen Kristalleinschlussverbindungen am Beispiel der Clathrate der Wirtverbindung 2,2’-bis(9-hydroxy-9-fluorenyl)biphenyl mit Aceton (polar) sowie Chloroform (unpolar). Durch die Kombination von Röntgenstrukturanalysen mit systematischen Messungen thermodynamischer Größen wie Löslichkeit, Einschluss-, Zersetzungs-, Lösungs- und Kristallisationsenthalpien konnten neue Erkenntnisse bezüglich der Struktur-Eigenschaftsbeziehungen sowie zur Rolle der Wirt-Gast Wechselwirkungen in den existierenden Einschlussverbindungen abgeleitet werden. Die Einschlussbildung bzw. Kristallisation verläuft für alle untersuchten Clathratphasen exotherm. Dies bedeutet, dass die Einschlussverbindungen gegenüber dem reinem Wirt energetisch stark begünstigt sind. Der bestimmende Beitrag hierfür resultiert aus der Bildung eines optimal gepackten Kristallgitters, während spezifische Wirt-Gast Wechselwirkungen nur eine untergeordnete Rolle spielen. Das Zersetzungsverhalten der verschiedenen Clathratphasen kann widerspruchsfrei aus der Packungsstruktur der Kristalle erklärt werden. info:eu-repo/classification/ddc/540 ddc:540
643	Vergleichende kalorimetrische Untersuchungen zur Ermittlung der mikrobiellen Aktivitäten von Pseudomonas putida Lißner, Andreas 16 December 2011 (has links) In der vorliegenden Arbeit wurden Untersuchungen zur mikrobiellen Aktivität von Pseudomonas putida DSM12735 durchgeführt. Als Messgröße diente die mikrobielle Wärmeleistung, basierend auf dem Stoffumsatz durch die Mikroorganismen. Ziel war es, die Vor- und Nachteile der verwendeten Kalorimeter herauszuarbeiten. Dafür wurden klassische Batch-Wachstumskurven aufgenommen. Ein weiteres Ziel bestand darin, eine Methode zur schnellen kalorimetrischen Detektion der mikrobiellen Aktivität insbesondere für die stationäre Phase zu entwickeln. In dieser Phase findet kein signifikanter Stoffumsatz statt. Durch das gezielte Auslösen einer zweiten Wachstumsphase und damit einem Stoffumsatz wird die mikrobielle Aktivität kalorimetrisch wieder messbar. Eingesetzt wurden folgende Kalorimeter: der Thermal Activity Monitor 2277 (TAM) mit den Kalorimetern Micro Reaction System 2250-4 ml und 2250-20 ml (kurz: TAM-4ml, TAM-20ml), das IC-Chip-Kalorimeter FCC22 (Institut für Physikalische Chemie, TU Freiberg) und das Kalorimeter Micro-DSC II (MDSC). info:eu-repo/classification/ddc/570 ddc:570
644	THE THERMAL SAFETY UNDERSTANDING OF MXENE ANODES IN LITHIUM-ION BATTERIES Lirong Cai (9174149) 29 July 2020 (has links) <p>Rechargeable lithium ion batteries (LIBs) are widely used in various daily life applications including electronic portable devices, cell phones, military applications, and electric vehicles throughout the world. The demand for building a safer and higher volumetric/gravimetric energy density LIBs has increased exponentially for electronic devices and electric vehicles. With the high energy density and longer cycle life, the LIBs are the most prominent energy storage system for electric vehicles. Researchers are further exploring for new materials with a high specific capacity, the MXene has been a promising new anode material for LIBs. The typical MXene material Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> has 447mAh/g theoretical capacity, which is higher than traditional graphite (372 mAh/g for LiC<sub>6</sub>) based anode.</p> <p>Though LIBs are used in most of the portable energy storage devices, LIBs are still having thermal runaway safety concern, which is caused by three main reasons: mechanical, electrical, and thermal abuse. The thermal runaway is caused by the initiation of solid electrolyte interface (SEI) degradation above 80 °C on the anode surface, generating exothermic heat, and further increasing battery temperature. The SEI is a thin layer formed on anode due to electrolyte decomposition during first few charging cycles. Its degradation at low temperature generates heat inside the LIBs and triggers the thermal runaway. The thermal runaway follows SEI degradation, electrolyte reactions, polypropylene separator melting, cathode decomposition and finally leads to combustion. The thermal runaway mechanism of graphite, which is the most common and commercialized anode material of LIBs, has been studied for years. However, the thermal safety aspects of the new MXene material has not been investigated yet. </p> <p>In this thesis, we primarily used differential scanning calorimetry (DSC) and specially designed multi module calorimetry (MMC) to measure exothermic and endothermic heat generated at <a>Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> </a>anode, associated with multiple chemical reactions as the temperature increases. The <i>in-situ</i> MMC technique is employed to study the interactions and chemical reactions of all the components (separator, electrolyte, cathode and MXene anode) in the coin cell for the first time, while the <i>ex-situ</i> DSC is used to investigate the reactions happened on anode side, including electrolyte, PVDF binder, MXene, SEI and intercalated Li. Along with other <a>complementary </a>instruments and methods, the morphological, structural and compositional studies are carried out using X-ray diffraction (XRD), Raman spectroscopy, scanning electron microscope (SEM), energy-dispersive X-ray spectroscopy (EDX), Brunauer-Emmett-Teller (BET) surface area measurement and electrochemical measurement to support the thermal analysis. The electrochemical and thermal runaway mechanism of conventional graphitic anode is studied and used for comparison with MXene<sub> </sub>anodes.</p> <p>The Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> thermal runaway is triggered by SEI decomposition around 120 °C analogous to conventional graphite. The thermal behavior of Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> anode is highly dependent on electrode material, surface area, lithiation states, surface morphology, structure and surface-terminating functional groups on Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub>, which provides more active lithium sites for exothermic reactions with the electrolyte. Especially the terminal groups (-OH, -F, =O, etc.) from the etching process affect the lithium ion intercalation and thermal runaway mechanism. With annealing treatment, the surface-terminating functional groups are modified and can achieve less exothermic heat release. By normalizing the total heat generation by specific capacities of the anode materials, it is observed that Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> (2.68 J/mAh) generates slightly less exothermic heat than graphite (2.72 J/mAh) indicating slightly safer nature of Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> anode. The <i>in-situ</i> thermal analysis results on the Ti<sub>3</sub>C<sub>2</sub>T<sub>z</sub> half-cell exhibited less total heat generation per mass (1.56 kJ/g) compared to graphite (1.59 kJ/g) half-cell. </p><br> Chemical Engineering Design Lithium-ion batteries Ti3C2Tz MXene anode Thermal runaway Surface-terminating functional groups Differential scanning calorimetry In-situ thermal analysis
645	Optimizing the Discovery and Processability of Biologically Derived Molecular Glass Host Materials for Photonic Applications Flynn, John J. 22 June 2020 (has links) No description available. Physical Chemistry Electromagnetics Materials Science Optics Long-Lifetime Materials Room Temperature Phosphorescence Steroid Host Guest Donor-Acceptor Chromophores Molecular Glass Differential Scanning Calorimetry Lithocholic Acid
646	Macronutrient Absorption Characteristics in Humans With Short Bowel Syndrome and Jejunocolonic Anastomosis: Starch Is the Most Important Carbohydrate Substrate, Although Pectin Supplementation May Modestly Enhance Short Chain Fatty Acid Production and Fluid Absorption Atia, Antwan, Girard-Pipau, Fernand, Hébuterne, Xavier, Spies, William G., Guardiola, Antonella, Ahn, Chul W., Fryer, Jon, Fengtian Xue,, Rammohan, Meena, Sumague, Mariquita, Englyst, Klaus, Buchman, Alan L. 01 March 2011 (has links) Background: Diet may play an important role in the management of patients with short bowel syndrome who have colon in continuity. However, macronutrient absorption has not been well characterized, and the most appropriate dietary constituents have not been well defined. Objective: To define carbohydrate absorption characteristics in patients with short bowel syndrome and determine the potential role of pectin as a dietary substrate. Methods: The authors studied the effect of a custom pectin-based supplement in 6 subjects (3 male/3 female) aged 29-67 years with jejunocolonic anastomosis, 4 of whom required long-term parental nutrition. Small intestinal absorption capacity, macronutrient and fluid balance, gastrointestinal transit time, and energy consumption were measured. Results: Data showed that 53% nitrogen, 50% fat, and 32% total energy were malabsorbed. In contrast, the majority (92%) of total carbohydrate was utilized. Fecal short-chain fatty acids (SCFAs) were increased, an indication of increased fermentation. Although only 4% of starch was recovered in stool, it is indicative of considerable starch malabsorption, thus providing the main carbohydrate substrate, for colonic bacterial fermentation. In contrast, non-starch polysaccharide was a relatively minor fermentation substrate with only 49% utilized. Eighty percent of the pectin was fermented. Supplementation was associated with increased total SCFAs, acetate, and propionate excretion. There was a trend observed toward greater fluid absorption (-5.9% ± 25.2%) following pectin supplementation. Nonsignificant increases in gastric emptying time and orocolonic transit time were observed. Conclusion : Despite malabsorption, starch is the primary carbohydrate substrate for colonic bacterial fermentation in patients with short bowel syndrome, although soluble fiber intake also enhances colonic SCFA production. fiber gastric emptying indirect calorimetry intestinal failure intestinal transit jejunocolonic anastomosis malabsorption nonstarch polysaccharides parental nutrition pectin short bowel syndrome short-chain fatty acids starch Internal Medicine
647	Mobilité moléculaire dans des systèmes polymères complexes anisotropes et confinés / Molecular dynamics in complex polymer systems : from anisotropy to confinement effects Monnier, Xavier 03 October 2017 (has links) L’objet de ce travail est d’étudier l’influence de l’anisotropie structurale, induite lors de la mise en forme d’un Polylactide (PLA), sur les dynamiques moléculaires de la phase amorphe. Deux procédés de mise en oeuvre sont retenus : l’électrofilage et la cristallisation induite par flux. Le premier permet d’aboutir à un système non-cristallin, lorsque le deuxième permet d’aboutir à un système semi-cristallin. Pour chaque système, une étude microstructurale est préalablement réalisée pour mettre en avant l’anisotropie structurale induite lors de la mise en oeuvre. Pour ce faire différentes techniques d’analyses sont utilisées : microscopie optique, microscopie électronique, diffraction des rayons X, calorimétrie à balayage différentielle (DSC) et calorimétrie à balayage rapide (FSC). L’utilisation de la FSC s’avère précieuse. Du fait des vitesses extrêmement rapide (1000 K.s-1) et de la diminution importante de la masse (dizaine de nanogrammes), la transition vitreuse et la cinétique de vieillissement physique sont au préalable étudiées dans le cas d’un PLA amorphe. Il est montré que les vitesses de refroidissement atteignable en FSC permettent d’accélérer les cinétiques de vieillissement physique. Les dynamiques moléculaires sont ensuite étudiées à travers le concept de coopérativité et le phénomène de vieillissement physique. Il est montré que l’orientation préférentielle induite dans le système non-cristallin aboutit à la formation de mésophase qui augmente la coopérativité, autrement dit les interactions intermoléculaires. Dans le cas du système semi-cristallin, les dynamiques moléculaires sont influencées par le couplage amorphe/cristal et le confinement des cristaux, et non pas par l’anisotropie structurale induite avant cristallisation. / The aim of this work is to investigate the molecular dynamics of Polylactide (PLA) subjected to structural anisotropy during its processing. To do so, two experimental set-ups were used: electrospinning and flow induced crystallization. The first one leads to non-crystalline system, while the second one leads to semi-crystalline system. For each system, the microstructure is investigated to highlight the structural anisotropy induced during the processing. Different experimental techniques are used: optical microscopy, electronic microscopy, X-ray diffraction, differential scanning calorimetry (DSC) and fast scanning calorimetry (FSC). FSC proves to be useful. Due to the high scanning rates (1000 K.s-1) and the decrease of the sample mass (few tens of nanogrammes), glass transition and physical aging kinetics are beforehand investigated in the case of a wholly amorphous PLA. It is shown that high cooling rates available by FSC allow to accelerate physical aging kinetics. Molecular dynamics are then investigated through concept of cooperativity and phenomenon of physical aging. It is shown that preferential orientation induced during electrospinning leads to the formation of mesophase, which increase cooperativity, namely the intermolecular interactions. With regard to semi-crystalline system, molecular dynamics are only affected by the coupling between amorphous/crystal and the confinement effect of the crystals, rather than the structural anisotropy induced before the crystallization step. Polylactide Nanofibres Sphérolites Cristallisation induite par flux Transition vitreuse Vieillissement physique Calorimétrie à balayage rapide Polylactide Nanofibers Spherulites Flow-induced crystallization Glass transition Physical aging Fast scanning calorimetry 539.1
648	The Role of Interface in Crystal Growth, Energy Harvesting and Storage Applications Ramesh, Dinesh 12 1900 (has links) A flexible nanofibrous PVDF-BaTiO3 composite material is prepared for impact sensing and biomechanical energy harvesting applications. Dielectric polyvinylidene fluoride (PVDF) and barium titanate (BaTiO3)-PVDF nanofibrous composites were made using the electrospinning process based on a design of experiments approach. The ultrasonication process was optimized using a 2k factorial DoE approach to disperse BaTiO3 particles in PVDF solution in DMF. Scanning electron microscopy was used to characterize the microstructure of the fabricated mesh. The FT-IR and Raman analysis were carried out to investigate the crystal structure of the prepared mesh. Surface morphology contribution to the adhesive property of the composite was explained through contact angle measurements. The capacitance of the prepared PVDF- BaTiO3 nanofibrous mesh was a more than 40% increase over the pure PVDF nanofibers. A comparative study of dielectric relaxation, thermodynamics properties and impact analysis of electrospun polyvinylidene fluoride (PVDF) and 3% BaTiO3-PVDF nanofibrous composite are presented. The frequency dependent dielectric properties revealed micro structural features of the composite material. The dielectric relaxation behavior is further supported by complex impedance analysis and Nyquist plots. The temperature dependence of electric modulus shows Arrhenius type behavior. The observed non-Debye dielectric relaxation in electric loss modulus follows a thermally activated process which can be attributed to a small polaron hopping effect. The particle induced crystallization is supported with thermodynamic properties from differential scanning calorimetric (DSC) measurements. The observed increase in piezoelectric response by impact analysis was attributed to the interfacial interaction between PVDF and BaTiO3. The interfacial polarization between PVDF and BaTiO3 was studied using density functional theory calculations and atomic charge density analysis. The results obtained indicates that electrospinning offers a potential way to produce nanofibers with desired crystalline nature which was not observed in molded samples. In addition, BaTiO3 can be used to increase the capacitance, desired surface characteristics of the PVDF nanofibers which can find potential application as flexible piezoelectric sensor mimicking biological skin for use in impact sensing and energy harvesting applications. Polyvinylidene fluoride (PVDF) Barium titanate (BaTiO3) Ultrasonication Electrospinning Design of experiments (DoE) Relaxation Interfaces Dielectric properties Differential scanning calorimetry (DSC) Piezoelectricity Impact sensing Electronic structure calculations.
649	Hodnocení stability vybraných rostlinných olejů / Evaluation of stability of selected vegetable oils Němečková, Lenka January 2010 (has links) This diploma thesis is focused on issues concerning the stability of selected vegetable oils which are used in cosmetic industry. The stability of eight oils without additives were determined by a differential scanning calorimeter. In the first phase, the temperatures of oil degradation were determined for different rates of heating, i.e. nonisothermal stabilities. They were consequetly used to calculate isothermal stabilities alias induction periods. The calculation of induction periods was completed by using integral isoconversional methods, which applied four different temperature functions. One of the temperature functions corresponded to Arrhenius equation while the others to non-Arrhenius functions. The confrontation of induction periods under standart conditions showed that an optimal temperature function to calculate oil stabilities is one of the non-Arrhenius functions in exponential form. We can state that all oils are degraded by similar, if not the same, mechanism. The specified stabilities, in periods of months, have proved the importance of using stabilizers and other additives in the commercial and technological use of vegetable oils.
650	OPTIMALIZACE TECHNOLOGICKÝCH VLASTNOSTÍ CEMENTOVÝCH FORMOVACÍCH SMĚSÍ / OPTIMIZATION OF TECHNOLOGICAL PROPERTIES OF CEMENT SAND MIXTURES Burianová, Klára January 2017 (has links) The work deals with optimization of the technological properties of cement-sand mixtures. The main objective is to find the correct mixture of the individual components which contribute to the rapid solidification of the mixture, hence shorter dismantling. The content is also of a method of measuring and recording during the plasticity of the mixture. Also assessment of the velocity of hydration heat cement mixture in the initial stage of the solidification process in the course of the strength properties of the mixture. To assess these phenomena was used calorimetric method used for measuring hydration heat cement mixture. Further measurements plasticity mixtures and mechanical and physical methods for measuring the compressive strength with the help of a measuring instrument LRU-D.

Search results