HIGH FREQUENCY DIELECTRIC PROPERTIES OF POLYIMIDES FOR MULTILAYER INTERCONNECT STRUCTURES

Hinedi, Mohamad Fahd, 1964-

January 1987

One of the most important electrical requirements in high performance electronic systems or high speed integrated circuits, is to process larger numbers of electrical signals at much higher speeds. Signal propagation delay must be minimized in order to maximize signal velocities. Therefore, material with low dielectric constant and low dissipation factor is being sought. In this thesis research measurements of dielectric constant and dissipation factor were performed on commercially available polyimides that are used in multilayer interconnect structures. Capacitor structures with a polyimide dielectric were measured up to a 1GHz frequency and 220°C temperature. Polyimides were concluded to be compatible for use in high performance systems such as multilayer interconnect structures.

Polyimides -- Electric properties.

Polyimides -- Thermal properties.

Dielectric measurements.

The use of thermal diffusivity to quantify tissue perfusion

Valvano, Jonathan Walker

January 1981

Thesis (Ph.D.)--Harvard-Massachusetts Institute of Technology Division of Health Sciences and Technology Program in Medical Engineering and Medical Physics, 1981. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND SCIENCE / Vita. / Includes bibliographical references. / by Jonathan Walker Valvano. / Ph.D.

Thermal diffusivity

Biomedical materials Thermal properties

Microcomputers

Perfusion (Physiology)

Thermistors

Synthesis and Characterization of Some Low and Negative Thermal Expansion Materials

Varga, Tamas

27 April 2005

Synthesis and Characterization of Some Low and Negative Thermal Expansion Materials Tamas Varga 370 pages Directed by Dr. Angus P. Wilkinson The high-pressure behavior of several negative thermal expansion materials was studied by different methods. In-situ high-pressure x-ray and neutron diffraction studies on several compounds of the orthorhombic Sc2W3O12 structure revealed an unusual bulk modulus collapse at the orthorhombic to monoclinic phase transition. In some members of the A2M3O12 family, a second phase transition and/or pressure-induced amorphization were also seen at higher pressure. The mechanism for volume contraction on compression is different from that on heating. A combined in-situ high pressure x-ray diffraction and absorption spectroscopic study has been carried out for the first time. The pressure-induced amorphization in cubic ZrW2O8 and ZrMo2O8 was studied by following the changes in the local coordination environments of the metals. A significant change in the average tungsten coordination was found in ZrW2O8, and a less pronounced change in the molybdenum coordination in ZrMo2O8 on amorphization. A kinetically frustrated phase transition to a high-pressure crystalline phase or a kinetically hindered decomposition, are likely driving forces of the amorphization. A complementary ex-situ study confirmed the greater distortion of the framework tetrahedra in ZrW2O8, and revealed a similar distortion of the octahedra in both compounds. The possibility of stabilizing the low thermal expansion high-temperature structure in AM2O7 compounds to lower temperatures through stuffing of ZrP2O7 was explored. Although the phase transition temperature was suppressed in MIxZr1-xMIIIxP2O7 compositions, the chemical modification employed was not successful in stabilizing the high-temperature structure to around room temperature. An attempt has been made to control the thermal expansion properties in materials of the (MIII0.5MV0.5)P2O7-type through the choice of the metal cations and through manipulating the ordering of the cations by different heat treatment conditions. Although controlled heat treatment resulted in only short-range cation ordering, the choice of the MIII cation had a marked effect on the thermal expansion behavior of the materials. Different grades of fluorinert were examined as pressure-transmitting media for high-pressure diffraction studies. All of the fluorinerts studied became nonhydrostatic at relatively low pressures (~1 GPa).

Negative thermal expansion

High pressure

X-ray diffraction

X-ray absorption spectroscopy

Pressure-induced amorphization

Thermal behavior

Materials Thermal properties

Cations

Expansion (Heat)

Energy efficiency interventions for residential buildings in Bloemfontein using passive energy techniques

Kumirai, Tichaona

January 2010

Thesis (M. Tech. (Mech. Eng.)) -- Central University of Technology, Free state, 2010 / The purpose of this research is to minimize the use of active systems in providing thermal comfort in single-family detached, middle to high income residential buildings in Bloemfontein. The typical case study house was selected according to the criteria as reviewed by Mathews et al., (1999). Measurements were taken for seven days (18 – 24 May 2009). The measurements were carried out in the winter period for Bloemfontein, South Africa. Ecolog TH1, humidity and temperature data logger was used in doing the measurements. These measurements included indoor temperatures and indoor relative humidity. Temperature swings of 8.43 ºC and thermal lag of 1 hour were observed. For the period of seven days (168 hours), the house was thermally comfortable for 84 hours. Thermal analysis for the base case house was done using Ecotect™ (building analysis software) and the simulated results were compared with the measured results. A mean bias error (MBE) of between 10.3% ≤≤11.5% was obtained on the initial calibration. The final calibration of the model yielded error between0.364% ≤≤0.365%. The final calibration model which presented a small error was adopted as the base case. Passive strategies were incorporated to the Ecotect™ model (final calibrated model) singly and in combination; then both thermal and space load simulations were obtained and compared to simulations from the original situation (base case) for assessing improvements in terms of thermal comfort and heating, ventilation and air conditioning (HVAC) energy consumption. Annual HVAC electricity savings of up to 55.2 % were obtained from incorporating passive strategies in combination. Incorporating passive strategies resulted in small improvements in thermal comfort.

Building materials - Thermal properties

Dwellings - Heating and ventilation

Dependence of physical and mechanical properties on polymer architecture for model polymer networks

Guo, Ruilan

27 February 2008

Effect of architecture at nanoscale on the macroscopic properties of polymer materials has long been a field of major interest, as evidenced by inhomogeneities in networks, multimodal network topologies, etc. The primary purpose of this research is to establish the architecture-property relationship of polymer networks by studying the physical and mechanical responses of a series of topologically different PTHF networks. Monodispersed allyl-terminated PTHF precursors were synthesized through ¡°living¡± cationic polymerization and functional end-capping. Model networks of various crosslink densities and inhomogeneities levels (unimodal, bimodal and clustered) were prepared by endlinking precursors via thiol-ene reaction. Thermal characteristics, i.e., glass transition, melting point, and heat of fusion, of model PTHF networks were investigated as functions of crosslink density and inhomogeneities, which showed different dependence on these two architectural parameters. Study of freezing point depression (FPD) of solvent confined in swollen networks indicated that the size of solvent microcrystals is comparable to the mesh size formed by intercrosslink chains depending on crosslink density and inhomogeneities. Relationship between crystal size and FPD provided a good reflection of the existing architecture facts in the networks. Mechanical responses of elastic chains to uniaxial strains were studied through SANS. Spatial inhomogeneities in bimodal and clustered networks gave rise to ¡°abnormal butterfly patterns¡±, which became more pronounced as elongation ratio increases. Radii of gyration of chains were analyzed at directions parallel and perpendicular to stretching axis. Dependence of Rg on ¦Ë was compared to three rubber elasticity models and the molecular deformation mechanisms for unimodal, bimodal and clustered networks were explored. The thesis focused its last part on the investigation of evolution of free volume distribution of linear polymer (PE) subjected to uniaxial strain at various temperatures using a combination of MD, hard sphere probe method and Voronoi tessellation. Combined effects of temperature and strain on free volume were studied and mechanism of formation of large and ellipsoidal free volume voids was explored.

Free volume distribution

Freezing point depression

Thermal characteristics

Molecular deformation

Inhomogeneities

Unimodal bimodal clustered architecutres

Model PTHF networks

Polymer networks

Topology

Materials Mechanical properties

Materials Thermal properties

Crosslinked polymers

Contribution à l'étude des parois complexes intégrant des matériaux à changements de phase : modélisation, expérimentation, et évaluation de la performance énergétique globale / No English title available

Guichard, Stéphane

14 May 2013

Cette thèse s'inscrit dans une démarche de maîtrise de l'énergie dans le secteur du bâtiment. Elle a pour but d'utiliser des solutions passives pour atteindre de hautes performances énergétiques. Une des solutions proposée, est l'utilisation de Matériaux à Changements de Phase (MCP) dans les parois. Les matériaux à formes stabilisée solide-liquide, sont utilisés pour stocker l'énergie thermique sous forme de chaleur latente. Le but de l'étude est de mettre en évidence l'impact réel des MCP en terme de complément d'isolation thermique et de proposer un modèle thermique pour prédire son impact sur le champ de température et par conséquent, sur le confort thermique. Une séquence expérimentale en environnement naturel et à grande échelle a été menée à l'île de La Réunion, où le climat est tropical et humide, avec un fort taux d'ensoleillement. Le rayonnement solaire étant important, il est nécessaire de minimiser les sollicitations solaires sur l'ensemble du bâtiment et en particulier la toiture, qui constitue la surface la plus exposée. La présence de lames d'airs au niveau de la toiture, qualifie celle-ci de complexe. Il est alors nécessaire de proposer une modélisation adaptée. Le modèle est couplé à un code de simulation thermique du bâtiment (ISOLAB) et permet de prédire d'une part, les profils de températures de chacune des surfaces constituant l'enveloppe du bâtiment, et d'autre part, d'évaluer l'impact des MCP sur le confort thermique pour différentes configurations. Selon une méthodologie, alliant Modélisation, Expérimentation et Validation (MEV), la démarche a permis de valider l'expérimentation dédiée et d'évaluer la capacité du modèle à prédire l'ensemble des données issues de l'expérimentation. / This Ph.D thesis focusses on energy control in buildings in order to reach high energetic performances by the use of passive means. One of the proposed solution is based on the use of Phase Change Materials (PCMs). Located into walls, PCMs allow to stock thermal energy into latent heat. The aim of the study is thus to put in evidence PCMs actual impacts on the thermal field of a building and its role as thermal insulation. For these considerations, a thermal model has been developed and validated. An experimental device has been set-up for the collection of data in field environment and for a human scale. The measurement sequence has been conducted at Reunion Island, for a hot and humid tropical climate. For the determination of the thermal behaviour of a commplex wall included PCMs, we proposed a generic model, able to predict many configurations. The model has been implemented in a multizone building simulation code (ISOLAB), for the prediction of wall temperature profiles and PCMs impact on the thermal comfort. Following a combined metholodogy, including modelling and experimentation for validation, we were able to validate the model for actual conditions and to evaluate the model's prediction accuracy.

Matériaux à changement de phase

Solutions passives

Stockage de l'énergie thermique

Isolation thermique

Parois complexes

Modélisation

Expérimentation

Validation expériementale de modèle

Materials Thermal properties

Passive solutions

Energy Storage

Thermal isolation

Complex walls

Modeling

Experimentation

Experimental validation model

Periodic flow physics in porous media of regenerative cryocoolers

Pathak, Mihir Gaurang

20 September 2013

Pulse tube cryocoolers (PTC) are a class of rugged and high-endurance refrigeration systems that operate without moving parts at their low temperature ends, and are capable of reaching temperatures down to and below 123 K. PTCs are particularly suitable for applications in space, guiding systems, cryosurgery, medicine preservation, superconducting electronics, magnetic resonance imaging, weather observation, and liquefaction of gases. Applications of these cryocoolers span across many industries including defense, aerospace, biomedical, energy, and high tech. Among the challenges facing the PTC research community is the improvement of system efficiency, which is a direct function of the regenerator component performance. A PTC implements the theory of oscillatory compression and expansion of the gas within a closed volume to achieve desired refrigeration. An important deficiency with respect to the state of art models dealing with PTCs is the limited understanding of the hydrodynamic and thermal transport parameters associated with periodic flow of a cryogenic fluid in micro-porous structures. In view of the above, the goals of this investigation include: 1) experimentally measuring and correlating the steady and periodic flow Darcy permeability and Forchheimer’s inertial hydrodynamic parameters for available rare-Earth ErPr regenerator filler; 2) employing a CFD-assisted methodology for the unambiguous quantification of the Darcy permeability and Forchheimer’s inertial hydrodynamic parameters, based on experimentally measured steady and periodic flow pressure drops in porous structures representing recently developed regenerator fillers; and 3) performing a direct numerical pore-level investigation for steady and periodic flows in a generic porous medium in order to elucidate the flow and transport processes, and quantify the solid-fluid hydrodynamic and heat transfer parameters. These hydrodynamic resistances parameters were found to be significantly different for steady and oscillatory flows.

Regenerator

ErPr

Nusselt

Porous media

Pore level

Periodic flow

Oscillatory flow

Darcy permeability

Forchheimer

Hydrodynamic

Thermal dispersion

Conjugate

Heat transfer

CFD

Pulse tube

Cryocooler

Cryogenics

Physics

Rare-Earth

Steady flow

Low temperature engineering

Materials at low temperatures

Porous materials Thermal properties

Porous materials

Aplicação da espectroscopia fotoacústica na determinação da temperatura de transição vítrea de polímeros / Photoacoustic spectroscopy applied to glass transition temperature determination of polymers

Talita Zanon Guzzo

23 February 2010

Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro / A espectroscopia fotoacústica (PAS) é uma técnica não destrutiva e muito utilizada na caracterização óptica e térmica de materiais. Ela é baseada no efeito fotoacústico que consiste, basicamente, na absorção de onda eletromagnética modulada e na geração de calor no interior do material em estudo (amostra), via processo de desexcitação não-radiativa. Dentre as muitas aplicações relacionadas à caracterização de materiais, recentemente, a técnica PAS vem sendo desenvolvida para estudos de transição de fase de segunda ordem. Entretanto, poucos trabalhos são encontrados na literatura com relação à aplicação da técnica PAS ao estudo da transição vítrea. Neste contexto, o objetivo deste trabalho é o de aplicar a técnica PAS na determinação da temperatura de transição vítrea de materiais poliméricos, de uma maneira inovadora com relação à célula fotoacústica e ao sistema de aquecimento. Para isso foi projetada e construída uma célula fotoacústica que possibilita a variação de temperatura da amostra, sem afetar a curva de resposta do microfone. Foi desenvolvido um sistema de aquecimento baseado no efeito Peltier, possibilitando fazer rampas de subida de temperatura, com várias velocidades, da temperatura ambiente até 130 C, de forma linear. Todo o aparato experimental foi testado e aplicado em várias amostras poliméricas: poliamida 6.0 (Nylon); poliestireno (PS-n1921 e PS-n2380); e poli(tereftalato de etileno) (PET). Os resultados obtidos foram: para o Nylon, ; para o PS-n1921, ; para o PS-n2380, ; e para o PET, . Estes resultados estão de acordo com os respectivos valores da temperatura de transição vítrea encontrados na literatura e mostram a potencialidade da técnica PAS ao estudo da transição vítrea de materiais poliméricos. / Photoacoustic spectroscopy (PAS) is a non-destructive technique and it has been largely applied to the thermal and optical characterization of materials. PAS technique is based on the photoacoustic effect which consist, basically, absorption of a modulated electromagnetic radiation and generation of heat inside of the material studied (sample), by a nonradiative deexcitation processes. Nowadays, among many PAS applications, effort are carried out to apply PAS technique for second-order phase transitions. However, only a few works can be found in the literature about glass transition studies with PAS technique. In this context, the main goal of this work is to apply PAS technique to determine glass transition temperature of the polymeric materials, based on the new photoacoustic cell configuration and on the new heating system. In this way, a photoacoustic cell was builted up for monitoring temperature variation of the sample, where the performance of the microphone was not affected. A heating system was developed based on the Peltier effect, in such way that it is possible to scan the temperature from the environment one up to 130 C, linearly at several speeds. The experimental apparatus was tested and applied to some polymeric materials: polyamide 6.0 (Nylon); polystyrene (PS-n1921 e PS-n2380); and poli(tereftalato de etileno) (PET). The results obtained were: Nylon, ; PS-n1921, ; PS-n2380, ; and PET, . These results are in a good agreement with the respective values of glass transition temperature found in the literature and show the PAS technique potentiality for glass transition studies in polymeric materials.

Espectroscopia acústica - ótica

Materiais Propriedades térmicas

Materiais Propriedades óticas

Caracterização de materiais

Espectroscopia fotoacústica

Transição de fase vítrea

Optoacoustic spectroscopy

Materials - Thermal properties

Materials - Optical properties

Materials Characterization

Photoacoustic spectroscopy

Glass transitions temperature

ENGENHARIA DE MATERIAIS E METALURGICA

Aplicação da espectroscopia fotoacústica na determinação da temperatura de transição vítrea de polímeros / Photoacoustic spectroscopy applied to glass transition temperature determination of polymers

Talita Zanon Guzzo

23 February 2010

Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro / A espectroscopia fotoacústica (PAS) é uma técnica não destrutiva e muito utilizada na caracterização óptica e térmica de materiais. Ela é baseada no efeito fotoacústico que consiste, basicamente, na absorção de onda eletromagnética modulada e na geração de calor no interior do material em estudo (amostra), via processo de desexcitação não-radiativa. Dentre as muitas aplicações relacionadas à caracterização de materiais, recentemente, a técnica PAS vem sendo desenvolvida para estudos de transição de fase de segunda ordem. Entretanto, poucos trabalhos são encontrados na literatura com relação à aplicação da técnica PAS ao estudo da transição vítrea. Neste contexto, o objetivo deste trabalho é o de aplicar a técnica PAS na determinação da temperatura de transição vítrea de materiais poliméricos, de uma maneira inovadora com relação à célula fotoacústica e ao sistema de aquecimento. Para isso foi projetada e construída uma célula fotoacústica que possibilita a variação de temperatura da amostra, sem afetar a curva de resposta do microfone. Foi desenvolvido um sistema de aquecimento baseado no efeito Peltier, possibilitando fazer rampas de subida de temperatura, com várias velocidades, da temperatura ambiente até 130 C, de forma linear. Todo o aparato experimental foi testado e aplicado em várias amostras poliméricas: poliamida 6.0 (Nylon); poliestireno (PS-n1921 e PS-n2380); e poli(tereftalato de etileno) (PET). Os resultados obtidos foram: para o Nylon, ; para o PS-n1921, ; para o PS-n2380, ; e para o PET, . Estes resultados estão de acordo com os respectivos valores da temperatura de transição vítrea encontrados na literatura e mostram a potencialidade da técnica PAS ao estudo da transição vítrea de materiais poliméricos. / Photoacoustic spectroscopy (PAS) is a non-destructive technique and it has been largely applied to the thermal and optical characterization of materials. PAS technique is based on the photoacoustic effect which consist, basically, absorption of a modulated electromagnetic radiation and generation of heat inside of the material studied (sample), by a nonradiative deexcitation processes. Nowadays, among many PAS applications, effort are carried out to apply PAS technique for second-order phase transitions. However, only a few works can be found in the literature about glass transition studies with PAS technique. In this context, the main goal of this work is to apply PAS technique to determine glass transition temperature of the polymeric materials, based on the new photoacoustic cell configuration and on the new heating system. In this way, a photoacoustic cell was builted up for monitoring temperature variation of the sample, where the performance of the microphone was not affected. A heating system was developed based on the Peltier effect, in such way that it is possible to scan the temperature from the environment one up to 130 C, linearly at several speeds. The experimental apparatus was tested and applied to some polymeric materials: polyamide 6.0 (Nylon); polystyrene (PS-n1921 e PS-n2380); and poli(tereftalato de etileno) (PET). The results obtained were: Nylon, ; PS-n1921, ; PS-n2380, ; and PET, . These results are in a good agreement with the respective values of glass transition temperature found in the literature and show the PAS technique potentiality for glass transition studies in polymeric materials.

Espectroscopia acústica - ótica

Materiais Propriedades térmicas

Materiais Propriedades óticas

Caracterização de materiais

Espectroscopia fotoacústica

Transição de fase vítrea

Optoacoustic spectroscopy

Materials - Thermal properties

Materials - Optical properties

Materials Characterization

Photoacoustic spectroscopy

Glass transitions temperature

ENGENHARIA DE MATERIAIS E METALURGICA