Global ETD Search

251	Mechanisms of lipid droplet formation by conjugated linoleic acid (CLA) isomers and its effects on cell viability Thiyam, Gayatri 10 January 2011 (has links) The putative peroxisome proliferator-activated receptor (PPAR) α ligand, conjugated linoleic acid (CLA) induced cytoplasmic lipid droplet (LD) formation in H4IIE rat hepatoma cells. Currently, the mechanism(s) by which CLA isomers affects hepatic LD formation is unclear. We have investigated the role of PPARα and fatty acid (FA) activation in the regulation of hepatic LD formation induced by CLA isomers [cis-9,trans-11 (c9,t11), trans-10,cis-12 (t10,c12)] and linoleic acid (LA) in an in vitro model of lipid accumulation. Dose response of c9,t11 and t10,c12 CLA isomers as well as LA in quiescent H4IIE cells was assessed by Oil Red O staining and subsequent quantification after 24 hours. LD formation was induced by the CLA isomers similar to LA in a dose-dependent manner. However, treatment with the acyl CoA synthetase (ACS) inhibitor, triacsin C, resulted in significantly reduced LD formation. A similar reduction in lipid accumulation was observed with the PPARα activator, Wy14643. Furthermore, CLA isomers promoted H4IIE viability at 60 µM but decreased viability at a higher dose of 180 µM. To further understand the role of PPARα in hepatic steatosis, we studied the level and phosphorylation of PPARα in livers of male lean and fa/fa Zucker rats fed either a control diet or fa/fa Zucker rats fed a CLA isomer (0.4% wt/wt c9,t11 or 0.4% wt/wt t10,c12) diet for 8 weeks. Immunoblotting results showed that only the t10,c12 CLA isomer significantly reduced phospho-PPARα S21 compared to the lean control (ln Ctl) and it was associated with a significant increase in the phosphorylation of p38 mitogen activated protein kinase (MAPK).These changes were not observed with the c9,t11 CLA isomer. Taken together, we have shown that CLA isomers directly induce LD formation in quiescent H4IIEs by activation of the lipid storage pathway which was significantly reduced by triacsin C or Wy14643. Also, we demonstrate for the first time that only the t10,c12 CLA isomer significantly reduced PPARα phosphorylation while it increased p38 MAPK phosphorylation. These results indicate that the anti-steatotic effects of the t10,c12 CLA isomer is associated with changes in PPARα phosphorylation and thereby its activity in a MAPK-independent manner. conjugated linoleic acid fatty liver lipid droplet cell viability
252	Plasma spray deposition of polymer coatings Bao, Yuqing January 1995 (has links) This work investigates the feasibility of the use of plasma spray deposition as a method of producing high performance polymer coatings. The work concentrates on the understanding of the processing of the plasma spraying of polymers, the behaviour of polymeric materials during deposition, and the study of process-structure-properties relationships. Processing modelling for the three stages of the evolution of a polymer deposit (droplet-splat-coating) has been carried out using heat transfer theory. A theoretical model is proposed which consists of three parts: the first part predicts the temperature profile of in-flight particles within plasma jet, the second part predicts the cooling of isolated splats impacting on a substrate and the third part, the heat transfer through the coating thickness. The heat transfer analysis predicts that the development of large temperature gradients within the particle is a general characteristics of polymers during plasma spraying. This causes difficulties for polymer particles to be effectively molten within the plasma jet without decomposition. The theoretical calculations have predicted the effect of processing parameters on the temperature, the degree of melting and decomposition of in-flight polymer particles. With the aid of the model, the conditions for the preparation of high integrity thermoplastic deposits have been established by the control of the plasma arc power, plasma spraying distance, feedstock powder injection, torch traverse speed and feedstock particle size. The optimal deposition conditions are designed to produce effective particle melting in the plasma, extensive flow on impact, and minimal thermal degradation. The experimental work on optimizing processing parameters has confirmed the theoretical predictions. Examination of polymer coating structures reveals that the major defects are unmelted particles, cracks and pores. Five major categories of pores have been classified. It also revealed a significant loss in crystallinity and the presence of a minor metastable phase in the plasma deposited polyamide coatings due to rapid solidification. The study has indicated that the molecular weight of a polymer plays an important role on the splat flow and coating structure. Under non-optimal deposition condition, substantial thermal degradation occurred for which a chain scission mechanism is proposed for plasma deposited polyamide coatings. There are difficulties in achieving cross-linking during plasma spray deposition of thermosets. The theoretical calculations predict that adequate cross-linking is unlikely in a coating deposited under normal conditions, but preheating the substrate to above the cross-linking temperature improves the degree of cross-linking of the coatings substantially. In addition, the coating thickness has a major effect on the degree of cross-linking of thermosets. The calculations also predict that lowering the thermal conductivity by applying a thermal barrier undercoat and using a faster curing agent to reduce time required for the cross-linking reaction can improve the degree of cross-linking of thermoset deposits. The experimental results for the degree of cross-linking and wear resistance confirmed these predictions. 667.9
253	Dynamics of soft interfaces in droplet-based microfluidics Brosseau, Quentin 14 April 2014 (has links) Diese Doktorarbeit untersucht die verschiedenen dynamischen Prozesse, welche sich an der Tropfenoberfläche abspielen, und der Methoden, die für deren Untersuchung verwendet wurden. Das Ziel dieser Arbeit ist es, die entscheidenden Eigenschaften, die einen Einfluss auf das mechanische Verhalten der Grenzfläche haben, zu identifizieren. Wir verwenden die hydrodynamisch erzwungene Deformation eines Tropfens in einem Mikrokanal, um die mechanischen Eigenschaften der Oberfläche zu untersuchen. Diese Methode wird auf drei verschiedene Fälle angewendet. Als erstes verfolgen wir die zeitliche Entwicklung einer Grenzflächenverformung, um die Dynamik der Tensidadsorption an einer Oberfläche zu untersuchen. Dabei kalibrieren wir die Tropfenverformung als Funktion von Tropfengröße und Oberflächenspannung. Diese Technik wird auf den Fall eines perfluorierten Tensids, welches von industriellem und wissenschaftlichem Interesse ist, angewendet. Wir zeigen die Möglichkeit von Messungen der dynamischen Oberflächenspannung auf Zeitskalen von zehn Millisekunden und gewinnen daraus kinetische Eigenschaften der Moleküle. Wir vergleichen die Dynamik, welche mit der klassischen Pendant-Drop-Methode gemessen werden kann mit denen der Mikrofluidik. Es zeigt sich, dass die Adsorption für den Pendant Drop von der Di usion begrenzt wird, während in der Mikrofluidik die Anbindung an die Oberfläche der langsamere Prozess ist. Der Unterschied entsteht durch das Flussprofil in der Mikrofluidik, welches konvektiven Transport induziert. Danach untersuchen wir die Verformung unter verschiedenen räumlichen Beschränkungen im mikrofluidischen Kanal. Die Tropfenverformung wird mit einer zweidimensionalen numerischen Simulationen und mit einem dreidimensionalen Modell eines Rotationsellipsoids verglichen. In beiden Fällen wird eine qualitative Übereinstimmung festgestellt, jedoch existieren auch spürbare Abweichungen vom Experiment. Die Abweichungen vom zweidimensionalen Modell ist erklärbar mit dem sinkenden Einfluss der viskosen Spannungen mit der Kanalhöhe, hervorgerufen durch Beiträge von Deformationen außerhalb der Beobachtungsebene, welche von dem Modell nicht wiedergegeben werden. Die Abweichungen vom dreidimensionalen Modell kommen von den räumlichen Beschränkungen, welche die Tropfenform von einem Rotationsellipsoid abweichend verformt. Die Untersuchung zeigt die Schwierigkeiten bei der Beschreibung von viskosen Kräfte für Abmessungen, die zu groß sind um als zweidimensional betrachtet zu werden, aber wo die Wechselwirkungen mit den Kanalwänden nicht vernachlässigbar sind. Wir diskutieren ebenfalls den Fall der trägen Relaxation des Tropfens bei Reynoldszahlen von Re 10, für welchen Oszillationen der Tropfenoberfläche beobachtet werden. Wir zeigen, dass die Oszillationen als hydrodynamische Analogie zu einer hookeschen Feder beschrieben werden können, wobei die Oberflächenspannung als Federkonstante fungiert und die Dämpfung durch die Viskosität der Flüssigkeit bestimmt wird. Die Methode liefert korrekte Ergebnisse sowohl für reine Grenzflächen als auch für Grenzflächen mit Tensiden, was zu einer zusätzliche Möglichkeit führt, die Oberflächenspannung aus der Frequenz der Verformungen zu bestimmen. Die viskose Relaxation wurde auch hierbei von den Kanalwänden beeinflusst. Als letztes wenden wir die Methode der mikrofluidischen Tensiometrie auf die Kinetik einer Polymerisationsreaktion auf der Tropfenoberfläche an. Der Einfluss der Reagenzkonzentration auf die Reaktionszeit wird untersucht, ebenso wie der E ekt der Gegenwart von Tensidmolekülen. Erste Ergebnisse dieser Untersuchung zeigen, dass die Deformation einer komplexen Grenzfläche nicht mehr allein durch die Oberflächenspannung beschrieben werden kann. Vielmehr muss die Beschreibung der mechanischen Eigenschaften der Grenzfläche notwendigerweise die Entstehung der Viskoelastizität an der Oberfläche mit in Betracht ziehen. Diese Erkenntnis erö net neue Möglichkeiten, mit Hilfe von Mikrofluidik die mechanischen Eigenschaften von komplexen Grenzflächen, wie zum Beispiel kolloidbesetzte Grenzflächen oder Membranen, zu charakterisieren. 530 Physik (PPN621336750) Interfacial rheology Droplet-based microfluidics Dynamic surface tension
254	Characterization of an Electrospray with Co-flowing Gas Sultan, Farhan 17 July 2013 (has links) In mass spectrometry an electrospray is commonly used as an ion source. At high sample flow rates a sheath co-flow of gas around the electrospray emitter is employed. The co-flow of gas reduces contamination and increases signal sensitivity in the mass spectrometer’s results. This work characterizes the operation of an electrospray with co-flowing air for various operating conditions. It is found that a co-flowing air has a negligible effect on droplet size for the spindle and cone jet modes while it only reduces the droplet size marginally in the unstable mode. In the high flow rate unstable mode, the addition of air seems to have no real effect on droplet size. In summary, the electrospray with co-flowing air produces a denser and more focused spray with similar droplet size and distribution than that of the un-nebulized spray. This explains why using co-flowing air in mass spectrometry applications improves the signal quality, since it allows for the focusing of droplets produced into the inlet and also aids in the breakup of larger droplets. Electrospray Characterization Co-Flowing Gas Nebulizer Droplet Size Cone Jet Mass Spectrometry Spray 0548
255	Characterization of an Electrospray with Co-flowing Gas Sultan, Farhan 17 July 2013 (has links) In mass spectrometry an electrospray is commonly used as an ion source. At high sample flow rates a sheath co-flow of gas around the electrospray emitter is employed. The co-flow of gas reduces contamination and increases signal sensitivity in the mass spectrometer’s results. This work characterizes the operation of an electrospray with co-flowing air for various operating conditions. It is found that a co-flowing air has a negligible effect on droplet size for the spindle and cone jet modes while it only reduces the droplet size marginally in the unstable mode. In the high flow rate unstable mode, the addition of air seems to have no real effect on droplet size. In summary, the electrospray with co-flowing air produces a denser and more focused spray with similar droplet size and distribution than that of the un-nebulized spray. This explains why using co-flowing air in mass spectrometry applications improves the signal quality, since it allows for the focusing of droplets produced into the inlet and also aids in the breakup of larger droplets. Electrospray Characterization Co-Flowing Gas Nebulizer Droplet Size Cone Jet Mass Spectrometry Spray 0548
256	Modeling And Numerical Analysis Of Single Droplet Drying Dalmaz, Nesip 01 August 2005 (has links) (PDF) MODELING AND NUMERICAL ANALYSIS OF SINGLE DROPLET DRYING DALMAZ, Nesip M.Sc., Department of Chemical Engineering Supervisor: Prof. Dr. H. &Ouml / nder &Ouml / ZBELGE Co-Supervisor: Asst. Prof. Dr. Yusuf ULUDAg August 2005, 120 pages A new single droplet drying model is developed that can be used as a part of computational modeling of a typical spray drier. It is aimed to describe the drying behavior of a single droplet both in constant and falling rate periods using receding evaporation front approach coupled with the utilization of heat and mass transfer equations. A special attention is addressed to develop two different numerical solution methods, namely the Variable Grid Network (VGN) algorithm for constant rate period and the Variable Time Step (VTS) algorithm for falling rate period, with the requirement of moving boundary analysis. For the assessment of the validity of the model, experimental weight and temperature histories of colloidal silica (SiO2), skimmed milk and sodium sulfate decahydrate (Na2SO4&amp / #8901 / 10H2O) droplets are compared with the model predictions. Further, proper choices of the numerical parameters are sought in order to have successful iteration loops. The model successfully estimated the weight and temperature histories of colloidal silica, dried at air temperatures of 101oC and 178oC, and skimmed milk, dried at air temperatures of 50oC and 90oC, droplets. However, the model failed to predict both the weight and the temperature histories of Na2SO4&amp / #8901 / 10H2O droplets dried at air temperatures of 90oC and 110oC. Using the vapor pressure expression of pure water, which neglects the non-idealities introduced by solid-liquid interactions, in model calculations is addressed to be the main reason of the model resulting poor estimations. However, the developed model gives the flexibility to use a proper vapor pressure expression without much effort for estimation of the drying history of droplets having highly soluble solids with strong solid-liquid interactions. Initial droplet diameters, which were calculated based on the estimations of the critical droplet weights, were predicted in the range of 1.5-2.0 mm, which are in good agreement with the experimental measurements. It is concluded that the study has resulted a new reliable drying model that can be used to predict the drying histories of different materials. QA Numerical Analysis 297-299.4
257	Scaling of effervescent atomization and industrial two-phase flow Rahman, Mohammad 06 1900 (has links) The objective of this thesis was to develop a novel understanding of the mechanics of two phase gas-liquid flows and sprays injected through industrial effervescent nozzles. This was done using detailed experimental investigations and scaling for two-phase flows and sprays. This study helps to quantify near-field liquid and gas phase statistics that are challenging and impossible to measure in the reactors due to inaccessibility restrictions. The development of nozzles is generally performed on air-water systems. My plan was to begin with the study of small-scale sprays (air and water) to compare to full scale industrial conditions at pilot operation (air-water) or at commercial operation (steam-bitumen), to determine size scaling relationships. The relationship between the lab scale air-water experiments and real industrial scale steam-bitumen has never been fully examined. Knowledge from this thesis will make the development of future nozzles with much less dependent on trial and error. This thesis was an attempt to establish fundamental scaling relationships for the prediction of two-phase spray behavior that can be applied directly to full scale industrial size nozzles that would be of very significant value to industries and to the scientific community in general. Understanding the performance of two phase nozzles through established scaling laws will aid in optimizing the two phase nozzle flow conditions and will serve as a major tool in nozzle design and development for future generation nozzles for many industrial applications. Multiphase Atomization Scaling Phase Doppler Particle Anemometer Nozzle Photonics Bubble Droplet
258	Investigation of Effervescent Atomization Using Laser-Based Measurement Techniques Ghaemi, Sina 11 1900 (has links) Effervescent atomization has been a topic of considerable investigation in the literature due to its important advantages over other atomization mechanisms. This work contributes to the development of both effervescent atomizers and also laser-based techniques for spray investigation In order to develop non-intrusive measurement techniques for spray applications, a procedure is suggested to characterize the shape of droplets using image-based droplet analyzers. Image discretization which is a major source of error in droplet shape measurement is evaluated using a simulation. The accuracy of StereoPIV system in conducting droplet velocity measurement in a spray field is also investigated. To assist in the design of effervescent atomizers, bubble formation during gas injection from a micro-tube into liquid cross-flow is investigated using a Shadow-PIV/PTV system. The generated spray fields of two effervescent atomizers which operate using a porous and a typical multi-hole air injector are compared using qualitative images and Shadow-PTV measurement. Effervescent atomization Shadowgraph particle analyzer Particle Image Velocimetry Droplet shape Discretization error Bubble formation
259	Efeito de adjuvantes nas propriedades físico-químicas da água e na redução de deriva em pulverizações sobre diferentes espécies de plantas daninhas Iost, Cristina Abi Rached [UNESP] 11 February 2008 (has links) (PDF) Made available in DSpace on 2014-06-11T19:28:36Z (GMT). No. of bitstreams: 0 Previous issue date: 2008-02-11Bitstream added on 2014-06-13T19:58:11Z : No. of bitstreams: 1 iost_car_me_botfca.pdf: 1768880 bytes, checksum: 15165f8112f914fcc04feae599644f1d (MD5) / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Este trabalho teve como objetivo avaliar o efeito de adjuvantes sobre algumas propriedades de soluções aquosas, como tamanho de gotas, tensão superficial dinâmica e ângulo de contato das gotas em diferentes superfícies, natural e artificial, bem como avaliar o efeito desses produtos sobre a deposição e a deriva utilizando como alvo três espécies de plantas daninhas (Euphorbia heterophylla, Ipomoea grandifolia e Brachiaria plantaginea). Seis formulações de adjuvantes (Antideriva®, Uno®, Pronto 3®, Li-700®, Supersil® e Silwet L-77®) foram avaliadas em soluções aquosas contendo a dose recomendada do produto comercial e o dobro dela. As avaliações de tamanho de gotas foram feitas com três diferentes pontas de pulverização (AXI 110 015, 110 02 e 110 03) por um equipamento a laser (Mastersizer, Malvern) na pressão de trabalho de 414 kPa. Os ângulos de contato formados pelas gotas em duas superfícies, uma hidrofílica (vidro) e outra hidrofóbica (óxido de alumínio), foram obtidos por análise de imagens capturadas por uma câmera digital. As avaliações de deposição e deriva das soluções aquosas associadas ou não aos adjuvantes e contendo o traçador azul brilhante (0,15% v/v), foram feitas sobre diferentes espécies vegetais, e com o auxílio de coletores laterais (placas de Petri). A quantificação do traçador foi por feita espectrofotometria. A tensão superficial dinâmica e o ângulo de contato formado sobre as superfícies adaxiais das folhas foram medidos por um tensiômetro. Em relação ao tamanho de gotas, o adjuvante Antideriva, com dobro da dose recomendada, foi o que apresentou os menores valores percentuais de volume de gotas com diâmetro menor que 100 µm e os maiores DMV, para todas as pontas em teste. As soluções que proporcionaram as maiores... / The aim of this work is to evaluate the effect of adjuvants on droplet size, dynamic surface tension and contact angle formed by the water drops in different surfaces, as well as evaluating the adjuvants effect on the deposit and the spray drift using three species of plants (Euphorbia heterophylla, Ipomoea grandifolia e Brachiaria plantaginea). We studied six adjuvants formulations (Antideriva , Uno , Pronto 3 , Li- 700 , Supersil and Silwet L-77 ) in water solution using the dosage recommended by the manufacturer and twice that dose. The droplet size of three different nozzles (AXI 110 015, 110 02 and 110 03), for a constant pressure of 414 kPa, were evaluated by a laser system. The contact angles of the drops in two surfaces (hydrophilic and hydrophobic) were obtained by the analysis of images captured by a digital camera. The evaluation of deposition and spray drift deposition of the solutions containing brilliant-blue dye (0.15 % v/v) were carried out in different plant species. The solutions were collected laterally using Petri dishes, and the brilliant-blue dye content quantified by absorption spectroscopy. The dynamic surface tension and the angle formed on the surfaces of the leaves were measured by a tensiometer. Regarding the droplet size, for all the nozzles tested the adjuvant Antideriva with twice the recommended dose presented the lowest percentage of spray volume in droplets with diameters smaller than 100µm, and highest VMD. The solutions that provided the highest reductions in the dynamic surface tension and the smallest contact angle were the ones with the adjuvants Silwet L-77 and Supersil for both appraised doses. The largest deposit average for I. grandifolia was obtained by using Uno with double of the dose; for B. ...(Complete abstract click electronic access below) Erva daninha Pulverização Defensivos agrícolas Fitossanidade Dynamic surface tension Droplet size Contact angle Spray deposit
260	Interaction of droplets and foams with solid/porous substrates Arjmandi-Tash, Omid January 2017 (has links) Current problems on the interaction of complex liquids (i.e. droplets or foams) with complex surfaces (i.e. soft deformable or porous surfaces) are addressed in the following areas: (1) wetting of deformable substrates and surface forces, (2) kinetics of wetting and spreading of non-Newtonian liquids over porous substrates, (3) kinetics of spreading of non-Newtonian solutions over hair, (4) free drainage of foams produced from non-Newtonian solutions, and (5) foam drainage placed on porous substrates. Equilibrium of liquid droplets on deformable substrates was investigated and the effect of disjoining pressure action in the vicinity of the apparent three phase contact line was taken into account. It was proven that the deformation of soft solids is determined by the action of surface forces inside the transition zone. Spreading/imbibition of blood, which is a power law shear thinning non-Newtonian liquid, over a dry porous layer was investigated from both theoretical and experimental points of view. It was found that blood droplet spreading/imbibition over porous substrates shows two different behaviours: (i) partial wetting case with three subsequent stages: initial fast spreading, constant maximum droplet base and the shrinkage of the droplet base; (ii) complete wetting case with only two stages: initial fast spreading and the shrinkage of the droplet base. The wetting of hair tresses by aqueous solutions of two commercially available polymers, AculynTM 22 (A22) and AculynTM 33 (A33) was investigated experimentally. Both A22 and A33 solutions demonstrate well pronounced shear thinning behaviour. Initial contact angle of the A22 and A33 solutions on hair tresses was about 100o. The A22 droplets remained on the hair tress after spreading for at least half an hour. However, a fast penetration of the A33 droplets inside the hair tresses was observed when advancing contact angle in the course of spreading reached a critical value of about 60o. This could be explained by Cassie-Wenzel wetting transition which is caused by filling the pores inside the porous media by liquid. The influence of non-Newtonian rheology of A22 and A33 solutions on foam drainage was also investigated experimentally and a new theory of foam drainage was presented for the case of free drainage. For lowly viscous polymeric solutions and under the assumption of rigid surface of the Plateau border, the predicted values of the time evolution of the foam height and liquid content were in good agreement with the experimental data. However, in the case of highly viscous solutions an interfacial mobility at the surface of the Plateau border has to be taken into account. A completely new theory of foam drainage placed on porous substrate was developed. It was found that there are three different regimes of the process: (i) a rapid imbibition, the imbibition into the porous substrate dominates as compared with the foam drainage; (ii) an intermediate imbibition, that is, the imbibition into the porous substrate and the rate of drainage are comparable; (iii) a slow imbibition, the rate of drainage inside the foam is higher than the imbibition into the porous substrate for a period of time and a free liquid layer is formed over the porous substrate. 541

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