Global ETD Search

221	Embedded active and passive methods to reduce the junction temperature of power and RF electronics Chen, Xiuping 22 May 2014 (has links) AlGaN/GaN high electron mobility transistors (HEMTs) have been widely used for high power and high frequency RF communications due to their fast switching and large current handling capabilities. The reliability of such devices is strongly affected by the junction temperature where the highest magnitude occurs in a local region on the drain side edge of the gate called the hotspot. Thus, thermal management of these devices remains a major concern in the design and reliability of systems employing AlGaN/GaN HEMTs. Due to the large power densities induced in these devices locally near the drain side edge of the gate, it is clear that moving thermal management solutions closer to the heat generation region is critical in order to reduce the overall junction temperature of the device. In this work, we explore the use of embedded microchannel cooling in the substrate of AlGaN/GaN HEMTs made on Si and SiC substrates and compare them to passive cooling techniques using Si, SiC, and diamond substrates. In addition, the impact of cooling fluids and harsh environmental conditions were considered. The study was performed using a combination of CFD and finite volume analysis on packaged AlGaN/GaN HEMTs. Active cooling using embedded microchannels were shown to have a significant impact on the heat dissipation over the passive cooling methods, approaching or exceeding that of diamond cooled devices. For vertical power devices (IGBT), embedded microchannels in the power electronics substrates were explored. In both the power devices and lateral AlGaN/GaN HEMTs, the use of embedded microchannels with nonlinear channel geometries was shown to be the most effective in terms of reducing the device junction temperature while minimizing the pumping power required. Gallium nitride Microchannel liquid cooling Semiconductor substrate HEMT IGBT Electronics Cooling Cooling Indium
222	A study on indium joints for low-temperature microelectronics interconnections Cheng, Xiaojin January 2011 (has links) For microelectronics used in the low-temperature applications, the understanding of their reliability and performance has become an important research subject characterised as electronics to serve under the severe or extreme service conditions. Along with the impact from the increased miniaturization of devices, the various properties and the relevant thermo-mechanical response of the interconnection materials to temperature excursion at micro-scale become a critical factor which can affect the reliable performance of microelectronics in various applications. Pure indium as an excellent interconnection material has been used in pixellated detector systems, which are required to be functional at cryogenic temperatures. This thesis presents an extensive investigation into the thermo-mechanical properties of indium joints as a function of microstructure, strain (loading histories-dependent) and temperature (service condition-sensitive), specifically in the areas as follows: (i) the interfacial reactions and evolution between indium and substrate during the reflow process (liquid-solid) and thermal aging (solid-solid) stages by taking low-temperature cycling into account; (ii) determination of the effects of joint thickness and the types of substrate (e.g. Cu or Ni) on the mechanical properties of indium joints, and the stress- and temperature-dependent creep behaviour of indium joints; (iii) the establishment of a constitutive relationship for indium interconnects under a wide range of homologous temperature changes that was subsequently implemented into an FE model to allow the analysis of the evolution of thermally-induced stresses and strains associated with a hybrid pixel detector. 621.3
223	Energetics of ligand binding to activate site of glutathione transferase M1-1 Kinsley, Nichole Michelle 14 November 2006 (has links) Student Number : 0002483R - MSc dissertation - School of Molecular and Cell Biology - Faculty of Science / Isothermal titration calorimetry was used to investigate the forces that drive ligand binding to the active site of rGST M1-1. In an attempt to gain insight into the recognition of non-substrate ligands by GSTs, this study also investigates interactions between rGST M1-1 and ANS, a non-substrate ligand. At 25 °C, complex formation between rGST M1-1 and GSH, GSO3 -, and S-hexylglutathione is characterised by a monophasic binding isotherm with Kd values of 38.5 mM, 2.1 mM and 0.2 mM, respectively. One molecule of each ligand is bound per monomer of rGST M1-1. Binding of these ligands is enthalpically favourable and entropically unfavourable with a resultant favourable Gibbs free energy, overall. The effects of temperature and buffer ionisation on the energetics of binding were studied. The enthalpic and entropic contributions for all three ligands exhibited temperature dependence over the temperature range investigated (5-30 °C). The Gibbs free energy showed negligible changes with increasing temperature due to enthalpy-entropy compensation. The temperature dependence of the binding enthalpy yielded heat capacity changes of – 2.69 kJ/mol/K and –3.68 kJ/mol/K at 25 °C for GSH and S-hexylglutathione binding and –1.86 kJ/mol/K overall for GSO3 -. The linear dependence of DH on temperature for GSO3 - binding to rGST M1-1 suggests the formation of a more constrained complex which limits the fluctuations in conformations of the mu-loop at the active site. The non-linear dependence of DH on temperature for GSH and Shexylglutathione binding to the enzyme suggests the formation of a complex that samples different bound conformations due to the mobility of the mu-loop even after ligand is bound. Calorimetric binding experiments in various buffer systems with different ionisation enthalpies suggest that the binding of GSH to rGST M1-1 is coupled to the deprotonation of the thiol of GSH while GSO3 - binding to rGST M1-1 is independent of the buffer ionisation. At 25 °C, the rGST M1-1#1;ANS association is represented by a monophasic binding isotherm with one molecule of ANS bound per monomer of rGST M1-1. The interaction is both enthalpically and entropically driven with a Kd value of 27.2 mM representing moderate affinity. The effect of temperature on the interaction was investigated over the temperature range of 5-30 °C. The linear dependence of the binding enthalpy on temperature indicates that no significant structural changes occur upon binding of ANS to the enzyme (DCp = -0.34 kJ/mol/K). The change in heat capacity associated with the interaction can be attributed to the burial of the polar sulphonate group of ANS and the exposure of the anilino and naphthyl rings to solvent as well as the possibility of weak electrostatic interactions between ANS and residues at the active site. The effect of ethacrynic acid, GSH, GSO3 - and S-hexylglutathione on the fluorescence of ANS was investigated in order to obtain some idea as to the location of the ANS binding site on rGST M1-1. ANS was displaced by GSO3 -, S-hexylglutathione and ethacrynic acid, while no displacement occurred upon binding of GSH to the active site of rGST M1-1. Displacement studies and molecular docking simulations indicate that ANS binds to the H-site of rGST M1-1 and the possibility of a second binding site for the molecule cannot be ruled out. Isothermal titration calorimetry non-substrate ligands GST enthalpic entropic Gibbs free energy enthalpy-entropy compensation
224	Effects of Thickness and Indenter Tip Geometry in Nanoindentation of Nickel Films Parakala, Padma 05 1900 (has links) Nanoindentation has become a widely used technique to measure the mechanical properties of materials. Due to its capability to deform materials in micro- and nano-scale, nanoindentation has found more applications in characterizing the deformation behavior and determining the mechanical properties of thin films and coatings. This research deals with the characterization of samples received from Center for Advanced Microstructures and Devices (CAMD) and Integran Technologies Inc., Toronto, Canada and the objective of this investigation was to utilize the experimental data obtained from nanoindentation to determine the deformation behavior, mechanical properties of thin films on substrates and bulk materials, and the effect of geometrically different indenters (Berkovich, cubecorner, and conical). X-ray diffraction (XRD), transmission electron microscope (TEM), scanning electron microscopy (SEM), and atomic force microscopy (AFM) analysis were performed on these materials to determine the crystal orientation, grain size of the material, and also to measure any substrate effects like pile-up or sin-in respectively. The results indicate that indentation size effect (ISE) strongly depends on shape of the indenter and less sensitive to penetration depth where as the hardness measurements depends on shape of indenter and depth of penetration. There is a negligible strain rate dependency of hardness at deeper depths and a significant increase in the hardness due to the decrease in grain size and results also indicate that there is no significant substrate effect on thin films for 10% and 20% of film thicknesses. Nanocrystalline material could not validate a dislocation based mechanisms deformation for indentation made by cubecorner and conical indenters in depths less than 1mm. Nickel films -- Mechanical properties. Berkovich tip conical tip cubecorner tip indentation size effect substrate effects
225	Modeling the behavior of the Linearly Tapered Slot Antenna Kelly, Thomas P. 12 1900 (has links) Approved for public release; distribution is unlimited / The Linearly Tapered Slot Antenna (LTSA) had been investigated and developed experimentally; its applications have primarily been based on empirical designs. An accurate theoretical model based on Moment Methods (MM) is developed here to study the radiation characteristics of the LTSA. Using the MM solutions to the reaction integral equation, this thesis presents an analysis to model and explain the LTSA behavior. The effects of variable design parameters on radiation patterns are studied. Discussion is augmented by relating predicted radiation patterns to calculated current distributions on the antenna surface. Conclusions are made regarding optimum designs for the LTSA. Relevant observations are made concerning the extensive computational tasks and the computer resources required for the MM model. / http://archive.org/details/modelingbehavior00kell / Major, United States Army LTSA Flare angle Substrate Dielectrical Antenna Planar antenna Radiation pattern Moment method The Linearly Tapered Slot Antenna
226	The Formation and Morphology of Nanoparticle Supracrystals Haubold, Danny, Reichhelm, Annett, Weiz, Alexander, Borchardt, Lars, Ziegler, Christoph, Bahrig, Lydia, Kaskel, Stefan, Ruck, Michael, Eychmüller, Alexander 09 September 2016 (has links) (PDF) Supracrystals are highly symmetrical ordered superstructures built up from nanoparticles via self-assembly. While the NP assembly has been intensively investigated, the formation mechanism is still not understood. To shed some light onto the formation mechanism, we are using one of the most common supracrystal morphologies, the trigonal structures, as a model system to investigate the formation process in solution. To explain the formation of the trigonal structures and determining the size of the supracrystal seeds formed in solution, we introduce the concept of substrate-affected growth. Furthermore, we show the influence of the NP concentration on the seed size and extend our investigations from Ag towards Au. 1. Suprakristalle substrate-affected growth supracrystals supercrystals formation mechanism silver nanoparticles self-assembly ddc:540 rvk:VA 1120
227	Biogas Production from Lignocelluloses : Pretreatment, Substrate Characterization, Co-digestion and Economic Evaluation Teghammar, Anna January 2013 (has links) Biogas production from organic materials can be used as a renewable vehicle fuel, provide heat and generate electricity and can thereby reduce the greenhouse gas emissions. This thesis focuses on the biogas production based on lignocelluloses. There is an abundant availability of lignocelluloses, constituting 50% of the total biomass worldwide. However, the biomass recalcitrance limits the microbial degradation as well as the biogas production from these types of materials. In the present work different pretreatment methods have been performed in order to decrease the biomass recalcitrance and improve the biogas production. Steam explosion pretreatment, together with the addition of sodium hydroxide and hydrogen peroxide, has been performed on lignocellulosic-rich paper tube residuals. The pretreatment has resulted in methane yields of up to 493 NmL/gVS, which is an increase by 107% compared with untreated material. Furthermore, the use of an organic solvent, N-methylmorpholine-N-oxide (NMMO), was evaluated as a pretreatment method for spruce (both chips and milled), rice straw, and triticale straw. The NMMO pretreatment resulted in 202, 395, 328, and 362 NmL CH4/g carbohydrates produced of these substrates, respectively, corresponding to an increase of between 400-1,200% compared with the untreated version of the same material. Moreover, the paper tube residuals have been co-digested with an unstable nitrogen-rich substrate mixture, mainly based on municipal solid waste. The addition of the lignocellulosic-rich paper tubes in a co-digestion process showed stabilizing effects and prevented the accumulation of volatile fatty acids with a subsequent reactor failure. Additionally, synergistic effects have been found leading to between 15-33% higher methane yields when paper tubes were added to the co-digestion process compared with the yields calculated from the methane potentials of the two substrates. Substrate characterization analysis can be used to study the changes on the lignocellulosic components after the pretreatment, relating the changes to the performance in the anaerobic digestion. Increased accessible surface area, measured by the Simons’ stain and the enzymatic adsorption methods, as well as decreased crystallinity, determined by using the Fourier Transform Infrared Spectroscopy, can all be linked to improved biogas production after pretreatment. Finally, the NMMO pretreatment on forest residues has been financially evaluated for an industrial scale process design. The base case that was evaluated simulated a case where pretreated forest residues were co-digested with the organic fraction of municipal solid waste to obtain optimal nutritional balance for the anaerobic digestion. This process has been found to be economically feasible with an internal rate of return of 20.7%. / <p>Akademisk avhandling som för avläggande av teknologie doktorsexamen vid Chalmers tekniska högskola försvaras vid offentlig disputation den 24 maj 2013, klockan 10.00 i KA,Kemigården 4, Göteborg</p> biogas lignocellulose pretreatment anaerobic digestion co-digestion substrate characterization economic evaluation Biotechnology
228	Étude et passivation des défauts introduits par la gravure de vias sur cellule photovoltaïque triple jonction De Lafontaine, Mathieu January 2016 (has links) Malgré l'augmentation constante de l'efficacité des cellules photovoltaïques multi-jonctions destinées au photovoltaïque concentré, des pertes de performances subsistent à haute concentration solaire. Elles sont principalement causées par un ombrage excessif dû aux métallisations ou par effet Joule à cause de la résistance série. Une des solutions à ce problème est de reporter le contact métallique en face avant sur la face arrière grâce à des vias métallisés et isolés électriquement. Avec cette architecture, les pertes dues à l'effet Joule et à l'ombrage seront limitées et des gains en efficacité sont attendus. Toutefois, l'intégration de vias sur des cellules photovoltaïques triple jonction favorise la recombinaison électron-trou en surface et peut provoquer une perte de performances de ces dispositifs. Ce mémoire présente les travaux de recherche effectués visant à étudier précisément cette problématique ainsi qu'à proposer des solutions pour limiter ces pertes. L'objectif est d'évaluer les pertes de performances de cellules photovoltaïques triple jonction suite à l'intégration de vias. Dans un second temps, l'objectif secondaire vise à limiter les pertes grâce à des traitements de passivation. Les résultats et solutions qu'apporte ce projet représentent une étape clé dans la réalisation de cette nouvelle architecture de contact électrique pour cellules photovoltaïques. En effet, les conclusions de ce projet de recherche permettent de valider la possibilité d'obtenir des gains en efficacité grâce à cette architecture. De plus, les procédés de microfabrication présentés dans ce projet de recherche proposent des solutions afin d'intégrer des vias sur ces hétérostructures tout en limitant les pertes en performances. Photovoltaïque concentré Cellule photovoltaïque multi-jonction Through substrate via contacts Via Passivation Hétérostructure III-V/Ge
229	Interfacial Phenomena in Two-Phase systems: Emulsions and slag Foaming Kapilashrami, Abha January 2004 (has links) In the present work studies were performed to provide understanding for further model development of the two-phase phenomena, film formation from o/w emulsions and slag foaming. The drying of o/w emulsions of different oil viscosities on hydrophobic and hydrophilic substrates was studied. The hydrophobic substrate was found to destabilise the oil droplets and to result in a different mechanism for forming continuous oil film. Studies of adsorption behaviour of a series of non-ionic diblock copolymers at relevant interfaces showed that the adsorption behaviour at hydrophobic and hydrophilic solid surfaces differed at high polymer concentration. Emulsion droplets were found to interact with the hydrophobic interface. Adsorption at silicone oil-water interface resembled adsorption at solid hydrophobic surfaces. Gas was generated through chemical reaction at the interface between two immiscible liquids and the bubbles formation from the generated was studied optically. The gas bubble size was seen to be uninfluenced by the reaction rate. However, bubble formation was seen to take place in one of the phases, held up at the interface before detaching from the interface with a surrounding aqueous film. It was argued that this may affect the final bubble sizes. Slag foaming at high temperatures was studied in laboratory scale with X-ray imaging under dynamic conditions. The foam displayed a fluctuating behaviour, which the presently available models are not able to take into account. The concept of foaming index was found to be unsatisfactory in describing the foaming behaviour under dynamic conditions, thus emphasizing the need for alternative theories. The rate of fluctuations was seen to be related to the difference between rate of gas generation and rate of gas escape from the system (Ug-Ue) as well as the bubble sizes. Thus, it seems like model development of dynamic foaming phenomenon has to take the effective chemical reaction rate as well as the bubble sizes into consideration Materials science film formation o/w emulsion substrate effect slag forming Materialvetenskap Materials science Teknisk materialvetenskap
230	Factors limiting benthic algal abundance in Virginia streams of the Coastal Plain Brandt, Michael 24 July 2009 (has links) Algae are important components of stream food webs and often used in biomonitoring assessments. Little is known regarding the factors that limit their abundance in streams of the VA Coastal Plain. The surficial geology of the Coastal Plain is predominately sandy deposits which comprise the dominant substrate in streams of this region. In a comparative study of five streams located near the VCU Rice Center, we quantified substrate composition, light availability, and nutrient concentrations to assess their relative importance in determining benthic algal abundance. The proportion of stream area comprised of hard substrates was a significant predictor of variation in benthic algal abundance (r²=0.66). An experimental component comparing algal colonization on artificial hard substrates (tile) to the natural substrate reinforced the importance of substrate stability. Hard substrates which included gravel and aggregated clay likely provided greater stability for algal colonization relative to sand and silt deposits, resulting in lower mortality from scouring and sedimentation. Incident solar radiation was a secondary factor affecting algal abundance with shaded streams exhibiting lower benthic chlorophyll. Where substrate and light conditions were favorable, relationships between benthic algal abundance and dissolved phosphorus concentrations were observed. Seasonal fluctuations were ameliorated by high light conditions and constant disturbances at sites lacking hard substrates which kept CHLa at consistently low levels. The mean proportion of FBOM C derived from benthic algae ranged from 10 to 24%. In spite of the consistently low observed benthic algal abundance at sandy unstable Coastal Plain streams, benthic algae are an important source of benthic organic matter. benthic algae phosphorus substrate nutrients biomonitoring light Environmental Sciences Physical Sciences and Mathematics

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