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21	Development of High Capacitance Films for Electrical Energy Storage Using Electrophoretic Deposition of BaTiO3 on Ultrasonically Etched Ni Harari, Berkan 13 October 2012 (has links) High capacitance devices were developed using rapid electrophoretic deposition (EPD) of barium titanate (BaTiO3) on ultrasonically etched nickel (Ni) substrates. The microstructural and electrical properties of films with varying thicknesses, sintering temperatures and substrate etching times were investigated to study their effect on the capacitance. Although increasing the capacitance was the primary goal, decreasing manufacturing costs and reducing environmental impact was also considered. After confirming the tetragonality and particle size of a 0.2 µm hydrothermal powder, it was dispersed in an aqueous-organic mixture of ethanol, acetone and water. A zeta potential of 50 mV was observed at the EPD pH level (6.8). Flocculation or coagulation was not likely in this situation. Therefore, mixing water with an organic solution was an effective method for reducing environmental impact while maintaining deposition quality. The presence of BaCO3 in the films was proven using X-ray diffraction. Other impurities such as TiO2 and NiO were not detected. A significant variation in the average grain size was not observed for films with different thicknesses whereas films sintered at different temperatures displayed greater variation. A bimodal pore size distribution in the samples suggested that the powder was agglomerated after deposition due to a high deposition voltage (20 V). Rapid deposition times of 2 to 8 seconds offered a potential for cost reduction compared to longer deposition times implemented in industry. Therefore the increased porosity was accepted. The dielectric constant of the films increased from 2900 to 6730 as the thickness increased from 17.75 µm to 47.5 µm. The dissipation factor decreased from 0.27 to 0.06 with increasing thickness. This behavior was attributed to a low dielectric constant interfacial layer and a higher dielectric leakage current at smaller thicknesses. The dielectric constant increased from 1700 to 6350 and the dissipation factor decreased from 0.23 to 0.04 as the sintering temperature increased from 1150°C to 1300°C. This was attributed to an increase in tetragonality with grain size and a decrease in porosity with sintering temperature. Finally, etching a substrate for 60 seconds increased its capacitance by 27.47% and using ultrasonic agitation further increased the capacitance by 8.75%. / Thesis (Master, Mechanical and Materials Engineering) -- Queen's University, 2012-10-12 00:54:53.915 Electrophoretic Deposition Energy Storage Barium Titanate Zeta Potential Advanced Ceramics Capacitors
22	Modifications de surface des nanodiamants : compréhension des mécanismes d’échanges électroniques et mise en évidence d’un effet thérapeutique / Nanodiamonds surface modifications : understanding of electron exchange mecanisms and evidence of a therapeutic effect Petit, Tristan 18 March 2013 (has links) A partir de l'étude des effets de la chimie de surface des Nanodiamants (NDs) sur leurs propriétés électroniques, cette thèse a permis la mise en évidence d'un effet thérapeutique des NDs sur des cellules humaines. En particulier, il a été montré que les NDs de détonation peuvent générer des radicaux libres oxygénés sous radiation ionisante, ce qui pourrait améliorer l'efficacité de certains traitements de radiothérapie actuels. Les échanges électroniques entre le coeur des NDs et leur environnement sont en effet favorisés après des traitements de surface, notamment d'hydrogénation et de graphitisation de surface. Les conditions expérimentales permettant d'obtenir des NDs hydrogénées (NDs-H) sous plasma d'hydrogène ont été optimisées sous ultravide, puis ont été utilisées pour préparer de grandes quantités de NDs-H sous forme pulvérulente. La même procédure a été appliquée pour la graphitisation de surface des NDs, en utilisant des recuits sous vide à haute température. L'effet de ces traitements de surface sur les propriétés d'interactions électroniques des NDs a été étudié après exposition à l'air ambiant, puis en dispersion dans l'eau. Ces traitements de surface assurent notamment un potentiel Zeta positif aux NDs, dont l'origine a été discutée. Enfin, les interactions des NDs avec plusieurs lignées de cellules tumorales humaines ont été étudiées et l'efficacité des NDs pour radiosensibiliser des cellules radiorésistantes sous irradiation gamma a été montrée, ouvrant de nouvelles perspectives d'applications des NDs en nanomédecine. . / In this thesis, a therapeutic effect of nanodiamonds (NDs) has been evidenced by investigating the role of NDs surface chemistry on their electronic properties. More precisely, the generation of reactive oxygen species from detonation NDs under ionizing radiation, which could improve current radiotherapy treatments, has been demonstrated. To this end, surface treatments facilitating electron transfer from NDs to their environment, namely hydrogenation and surface graphitization, were developed. Experimental conditions ensuring an efficient hydrogenation by hydrogen plasma were determined under ultrahigh vacuum, before being used to prepare large quantities of NDs in powder phase. A similar procedure was applied to the surface graphitization of NDs, performed by annealing under vacuum at high temperature. The impact of such surface treatments on the electronic interaction properties of NDs has been investigated under ambient air and after dispersion in water. These surface treatments induce a positive Zeta potential to NDs in water, which origin has been discussed. Finally, their interactions with human tumor cells were observed. Radiosensitization of tumor cells using NDs under gamma irradiation was demonstrated, opening new perspectives for NDs in nanomedicine. Nanodiamant Chimie de surface Transfert électronique Potentiel Zeta Radiosensibilisation Nanodiamond Surface chemistry Electron transfer Zeta Potential Radiosensitization
23	An Investigation into Formulation and Therapeutic Effectiveness of Nanoparticle Drug Delivery for Select Pharmaceutical Agents Cooper, Dustin 01 May 2016 (has links) Drug based nanoparticle (NP) formulations have gained considerable attention over the past decade for their use in various drug delivery systems. NPs have been shown to increase bioavailability, decrease side effects of highly toxic drugs, and prolong drug release. Furthermore, polymer based, biodegradable nanodelivery has become increasing popular in the field of NP formulation because of their high degree of compatibility and low rate of toxicity. Due to their popularity, commercially available polymers such as poly lactic acid (PLA), poly glycolic acid (PGA) and polylactic-co-glycolic acid (PLGA) are commonly used in the development and design of new nano based delivery systems. Nonsteriodal anti-inflammatory drugs (NSAIDs) are commonly used for the treatment of pain and inflammation. NSAIDs such as diclofenac and celecoxib function by blocking cyclooxygenase expression and reducing prostaglandin synthesis. Unfortunately, the pharmacological actions of NSAIDs can lead to the development of several adverse side effects such as gastrointestinal ulceration and bleeding. The aim of this study was to formulate and optimize diclofenac or celecoxib entrapped polymer NPs using an emulsion-diffusion-evaporation technique. NP formulations were evaluated based on specific formula parameters such as particle size, zeta potential, morphology, and entrapment efficiency. Effects of stabilizer type, stabilizer concentration, centrifugal force, drug amount, and/or emulsifier (lecithin) on nanoparticle characterization were examined for formula optimization. Results of the formulation studies showed that NPs developed using polylactide-co-glycolide (PLGA) polymers and the stabilizer didodecyldimethylammonium bromide (DMAB) demonstrated enhanced stability, drug entrapment, and reduced particle size. These findings demonstrate an effective method for polymer NP formulation of diclofenac or celecoxib. Furthermore, the results reported herein support a novel method of drug delivery that may function to reduce known adverse effects of these pharmacotherapeutic agents. Nanoparticle Formulation Drug Delivery Polymer DMAB PVA Celecoxib Diclofenac PLGA Zeta Potential Nanomedicine Pharmaceutics and Drug Design
24	Measurement of stability and size of colloidal particles in aqueous suspension Mateos González, Eduardo January 2019 (has links) This project focused on the study of self-assembling systems that can be inuenced by an external magnetic field, following the PhD research of Hauke Carstensen. My role was to study the behavior of beads and to optimize the tunable parameters so that the main force driving the dynamics of the system is the magnetic dipolar interaction between beads. To make sure that no other force plays an important role, we checked a number of things, the most problematic of which is flocculation in the colloid, which may happen if some beads get stuck to each other; to prevent them from aggregating we have to make sure that they have a large zeta potential, which will result in an electrically repulsive force between beads and will thus increase the stability of the colloid. We also have to make sure that other forces in the sample do not exceed the magnitude of magnetic forces between particles; examples of such forces can be the drag experienced while moving in the viscous ferrofluid, the gravity force or the random thermal movement of the molecules in the fluid. In order to study these efects, I measured the zeta potential of the magnetic and non-magnetic beads and later I added a surfactant compound (SDS) to our sample in order to increase said potential. Self-assembling systems colloid zeta potential SDS Condensed Matter Physics Den kondenserade materiens fysik
25	A fundamental study of bubble-particle interactions through zeta-potential distribution analysis Wu, Chendi 06 1900 (has links) Understanding the mechanism of bubble-particle interactions plays a critical role in advancing flotation technology. In this study, submicron size bubbles with an average diameter less than 1 μm and a life time of at least several hours were generated using a novel hydrodynamic cavitation method. Effect of mechanical force and water chemistry on generation and stability of submicron size bubbles is investigated. With recent development in measuring zeta potential distributions of colloidal systems, interactions of bubbles and fine solid particles in various electrolyte, surfactant and frother solutions as well as in industrial process water were studied using the stable submicron size bubbles generated by hydrodynamic cavitation. The outcome of this study provides not only a better understanding of bubble-particle attachment mechanism and its role in flotation, but also a direct evidence of armour-coating of bubbles and enhanced bubble-particle interactions by in situ gas nucleation. / Chemical Engineering Bubble-particle interactions Zeta-potential distribution Submicron size bubble generation In situ gas nucleation Hydrodynamic cavitation
26	An investigation of the effects of polymer partitioning on fines retention Miller, Charles E. 01 January 1989 (has links) No description available. Adsorption Fines Long fibers Papermaking Polymers Retention Retention aids Zeta potential
27	An investigation of the relation between carboxyl content and zeta potential Clapp, Richard Thomas 01 January 1972 (has links) No description available. Chemistry, Physical and theoretical Photochemistry Carboxyl groups Zeta potential Cellulose fibers Dacron
28	A Parametric Comparative Study Of Electrocoagulation And Coagulation Of Aqueous Suspensions Of Kaolinite And Quartz Powders Gulsun Kilic, Mehtap 01 December 2009 (has links) (PDF) Mineral treatment processes generally produce wastewaters containing ultrafine and colloidal particles that cause pollution upon their discharge into environment. It is essential that they should be removed from the wastewater before discharge. This study was undertaken by using synthetic turbid systems containing kaolinite and quartz particles in water with the amount of 0.20 g/L and 0.32 g/L, respectively. Removal of the turbidity was tried in two ways / electrocoagulation with aluminum anode and conventional coagulation with aluminum sulfate. Several key parameters affecting the efficiency of electrocoagulation and coagulation were investigated with laboratory scale experiments in search of optimal parameter values. Optimal values of the parameters were determined on the basis of the efficiency of turbidity removal from ultrafine suspensions. The parameters investigated in the study were suspension pH, electrical potential, current density, electrocoagulation time, and aluminum dosage. This study was also performed to compare electrocoagulation and conventional coagulation regarding the pH ranges under investigation and coagulant dosages applied. A comparison between electrocoagulation and coagulation was made on the basis of total dissolved aluminum, revealing that electrocoagulation and coagulation were equally effective at the same aluminum dosage for the removal of ultrafine particles from suspensions. Coagulation was more effective in a wider pH range (pH 5-8) than electrocoagulation, which yielded optimum effectiveness in a relatively narrower pH range around 9. In both methods, these pH values corresponded to near-zero zeta potentials of coagulated kaolinite and quartz particles. The mechanism for both coagulation methods was aggregation through charge neutralization and/or enmeshment in aluminum hydroxide precipitates. Furthermore, the experimental results confirmed that electrocoagulation could display some pH buffering capacity. The kinetics of electrocoagulation was very fast (&lt / 10 min) in approaching a residual turbidity, which could be modeled with a second-order rate equation. Q General Science 1-385
29	Effect Of Carbonate Alkalinity On The Flocculation Behavior Of Hematite Molaei, Aysan 01 August 2012 (has links) (PDF) As high grade iron ore deposits are rapidly depleted, the minerals industry is increasingly obliged to enrich their ores and process lower grade iron ores. Production of large quantities of fine ores as tailings or by-products in mining operations and mineral liberation at fine particle sizes have led to the development of concentration methods employed to fine ores. Selective flocculation is one of the beneficial methods which can be used in recovering of very fine particles It is obvious that process water chemistry has a significant influence on the flocculation efficiency, and the water chemistry is deeply affected by carbon dioxide dissolution. Carbonate content of natural waters regulated by CO2, carbonicacid and solid carbonatesis known as &lsquo / carbonate alkalinity&rsquo / whichmay be an important factor in flocculation especially at alkaline pH. Selective flocculation of iron ores is usually run at around pH 11 where carbonate alkalinity could be rather high. There have been no reports in literature regarding the effect of carbonate alkalinity on the flocculation behavior of iron oxides, mainly hematite. In this study, the flocculation behavior of iron ores with starch under different alkalinities has been investigated. The extent of flocculation has been assessed by settling rate and suspended solid content measurements at different starch doses and pH values. Zeta potential measurements and starch adsorption studies were carried out to explain these effects by carbonate alkalinity. According to the results, flocculation is enhanced by addition of low amount of carbonate alkalinity, less than 2.4 mEq/L. However, adding the higher amount of alkalinity adversely affected the flocculation of hematite. Similar behavior was also observed during the starch adsorption tests, larger amount of starch wasadsorbed by hematite in low alkalinity compared to high alkalinity. Zeta potential measurements indicate that, by increasing the carbonate alkalinity of suspension, zeta potential values of solids will become more negativeleading to an increase in the stability of suspension and then adversely affecting flocculation. Therefore, as carbonate alkalinity has a significant effect on the flocculation of hematite, it should be seriously taken into account to optimize the selective flocculation of hematite ores. TN Mining Engineering, Metallurgy. 1-997
30	Role Of Interfacial Phenomena In Bioprocessing Of Minerals Using Bacillus Polymyxa Shashikala, A R 02 1900 (has links) In recent years there has been growing interest in bio-mineral processing due to its low operating costs and its application in processing lean-grade ores. Bioprocessing is a good alternative to conventional hydrometallurgy process in mineral processing. In recent times microorganisms have been used as surface modifiers in processes such as froth flotation and flocculation. The surface properties of microbes and minerals such as zeta potential and surface hydrophobicity play a major role in determining adhesion of microorganisms to minerals and hence, the efficiency of flocculation and flotation. These properties also depend on solution conditions such as pH and ionic strength. Adhesion of microorganisms to mineral surfaces can alter the surface properties of the minerals. Such surface modification imparting hydrophobicity or hydrophilicity is used in flocculation and flotation of fine particles. In this research work the effect of ionic strength and pH in deteraiining the surface properties and hence adhesion of the bacterium Bacillus polymyxa to minerals such as hematite, quartz and coal has been studied in detail. The effect of the ionic strength and pH on the electrokinetics of the minerals and bacteria and its subsequent effect on adhesion and flocculation were investigated in detail. Contact angle measurements along with the zeta potential results were used to calculate the interaction energies between the mineral and the microorganism to establish a mechanism for the interaction. The following major conclusions can be drawn from this study. Results indicate that increase in the ionic strength significantly changes the zeta potential of hematite and bacteria without varying the isoelectric point. Increase in the ionic strength caused very little change in the zeta potential of quartz and coal. The adhesion of bacterial cells on to the minerals was found to be dependent on pH, ionic strength and conditioning time. Adhesion of bacterial cells was found to be more on hematite and coal when compared to quartz. The adsorption isotherms of Bacillus polymyxa cells with respect to all the three minerals were found to obey Langmuir isotherm. Flocculation studies demonstrated that the settling rate of hematite and coal was enhanced in presence of bacterial cells and electrolyte. However quartz settled much slower under the same conditions indicating that the quartz particles are being dispersed. Thus, selective flocculation of hematite and coal is possible which can be used in separating them from quartz effectively. The different components of total interaction energy arising from Lifshitz-van der Waal forces, acid/base forces and electrostatic forces were calculated using the van Oss approach. Calculation of the components of the acid base free energy showed that coal and hematite were hydrophobic compared to quartz and the bacterium. From total interaction energy calculation based on the extended DLVO theory, hematite and coal were found to have a net negative interaction energy in acidic pH values and hence attractive forces are predominant. Quartz was found to have a net repulsive energy at all the pH values at low ionic strengths but increase in ionic strength the interaction energy become attractive. The AGLW values of quartz was found to be attractive which is probably responsible for bacterial adhesion onto quartz. Metallurgy Bacterial Leaching Bacillus Polymyxa Zeta Potential Bioflocculation Flocculation Mineral Processing

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