Global ETD Search

1	The effect of internal stress on diffusion Chung, Samwon January 1995 (has links) No description available. Engineering, Materials Science internal stress diffusion
2	INVESTIGATING THE INTERNAL STRESS/STRAIN STATE OF THE FOOT USING MAGNETIC RESONANCE IMAGING AND FINITE ELEMENT ANALYSIS Petre, Marc Thomas 08 June 2007 (has links) No description available. Diabetes Ulcer Plantar Pressure Internal Stress Therapeutic Footwear
3	Early stage sintering and PLAL fragmentation of MgO powders Chen, Pei-Ru 04 July 2012 (has links) The specific surface area reduction and pore size distribution coupled with N2 adsorption-desorption hysteresis isotherm were studied in the temperature range of 1400-1550¢J for periclase MgO powder having 0.1£gm in size and with face-centered cubic structure. The apparent activation energy of such a rapid coarsening-coalescence process for MgO powder was estimated as 181¡Ó3kJ/mol. The minimum temperature for sintering/coarsening/coalescence of submicron MgO particles was estimated to be near 1300¢J based on the extrapolation of steady specific surface area reduction rates to zero. Pulsed laser ablation (PLA) of periclase MgO powders in water was conducted under Q-switch mode and specified water height and water depth (10 mm) for an accumulation time of 5 and 20 minutes at 10 Hz. Such a PLA process has successfully synthesized nanosized and protonated MgO particles from Mg(OH)2 and lamellar precusors, implying the three phases may co-exist at high pressure and temperature conditions upon dynamic shock loading. A significant internal compressive stress up to 10 GPa was built up for the MgO but not the readily relaxed Mg(OH)2 nanocondensates. The lamellae-derived Mg(OH)2 tended to undergo a dehydroxylation process to become MgO following a specific crystallographic relationship, i.e. lamellar basal layer parallel to Mg(OH)2(0001) and MgO(111). The minimum band gap of the colloidal solution of MgO/Mg(OH)2/lamellae was lowered to ca. 5.2eV after the PLA process. BET early-stage sintering MgO internal stress nanocondensate Mg(OH)2 PLAL in water lamellae
4	Structure and Properties of Electrodeposited Nanocrystalline Ni and Ni-Fe Alloy Continuous Foils Giallonardo, Jason 09 January 2014 (has links) This research work presents the first comprehensive study on nanocrystalline materials produced in bulk quantities using a novel continuous electrodeposition process. A series of nanocrystalline Ni and Ni-Fe alloy continuous foils were produced and an intensive investigation into their structure and various properties was carried out. High-resolution transmission electron microscopy (HR-TEM) revealed the presence of local strain at high and low angle, and twin boundaries. The cause for these local strains was explained based on the interpretation of non-equilibrium grain boundary structures that result when conditions of compatibility are not satisfied. HR-TEM also revealed the presence of twin faults of the growth type, or “growth faults”, which increased in density with the addition of Fe. This observation was found to be consistent with a corresponding increase in the growth fault probabilities determined quantitatively using X-ray diffraction (XRD) pattern analysis. Hardness and Young’s modulus were measured by nanoindentation. Hardness followed the regular Hall-Petch behaviour down to a grain size of 20 nm after which an inverse trend was observed. Young’s modulus was slightly reduced at grain sizes less than 20 nm and found to be affected by texture. Microstrain based on XRD line broadening was measured for these materials and found to increase primarily with a decrease in grain size or an increase in intercrystal defect density (i.e., grain boundaries and triple junctions). This microstrain is associated with the local strains observed at grain boundaries in the HR-TEM image analysis. A contribution to microstrain from the presence of growth faults in the nanocrystalline Ni-Fe alloys was also noted. The macrostresses for these materials were determined from strain measurements using a two-dimensional XRD technique. At grain sizes less than 20 nm, there was a sharp increase in compressive macrostresses which was also owed to the corresponding increase in intercrystal defects or interfaces in the solid. nanocrystalline nickel nickel-iron characterization properties hardness Young's modulus microstrain internal stress grain boundary 0794
5	Structure and Properties of Electrodeposited Nanocrystalline Ni and Ni-Fe Alloy Continuous Foils Giallonardo, Jason 09 January 2014 (has links) This research work presents the first comprehensive study on nanocrystalline materials produced in bulk quantities using a novel continuous electrodeposition process. A series of nanocrystalline Ni and Ni-Fe alloy continuous foils were produced and an intensive investigation into their structure and various properties was carried out. High-resolution transmission electron microscopy (HR-TEM) revealed the presence of local strain at high and low angle, and twin boundaries. The cause for these local strains was explained based on the interpretation of non-equilibrium grain boundary structures that result when conditions of compatibility are not satisfied. HR-TEM also revealed the presence of twin faults of the growth type, or “growth faults”, which increased in density with the addition of Fe. This observation was found to be consistent with a corresponding increase in the growth fault probabilities determined quantitatively using X-ray diffraction (XRD) pattern analysis. Hardness and Young’s modulus were measured by nanoindentation. Hardness followed the regular Hall-Petch behaviour down to a grain size of 20 nm after which an inverse trend was observed. Young’s modulus was slightly reduced at grain sizes less than 20 nm and found to be affected by texture. Microstrain based on XRD line broadening was measured for these materials and found to increase primarily with a decrease in grain size or an increase in intercrystal defect density (i.e., grain boundaries and triple junctions). This microstrain is associated with the local strains observed at grain boundaries in the HR-TEM image analysis. A contribution to microstrain from the presence of growth faults in the nanocrystalline Ni-Fe alloys was also noted. The macrostresses for these materials were determined from strain measurements using a two-dimensional XRD technique. At grain sizes less than 20 nm, there was a sharp increase in compressive macrostresses which was also owed to the corresponding increase in intercrystal defects or interfaces in the solid. nanocrystalline nickel nickel-iron characterization properties hardness Young's modulus microstrain internal stress grain boundary 0794
6	The role of internal stresses on the plastic deformation of the Al–Mg–Si–Cu alloy AA6111 Poole, Warren J., Proudhon, H., Wang, X., Brechet, Y. January 2008 (has links) In this work, we have investigated the internal stress contribution to the flow stress for a commercial 6xxx aluminium alloy (AA6111). In contrast to stresses from forest and precipitation hardening, the internal stress cannot be assessed properly with a uniaxial tensile test. Instead, tension-compression tests have been used to measure the Bauschinger stress and produce a comprehensive study which examines its evolution with i) the precipitation structure and ii) a wide range of applied strain. A large set of ageing conditions was investigated to explore the effect of the precipitation state on the development of internal stress within the material. It is shown that the Bauschinger stress generally increases with the applied strain and critically depends on the precipitate average radius and is thus linked to the shearable/non shearable transition. Further work in the case of non-shearable particles shows that higher strain eventually lead to particle fracture and the Bauschinger stress then rapidly decreases. Following the seminal work of Brown et al, a physically based approach including plastic relaxation and particle fracture is developed to predict the evolution of the internal stress as a function of the applied strain. Knowing the precipitation structure main characteristics –such as the average precipitate radius, length and volume fraction– allows one to estimate accurately the internal stress contribution to the flow stress with this model. AA6111 internal stress Aluminum Manganese Silicon Copper Al-Mg-Si-Cu plastic deformation Bauschinger
7	Intercultural Couples’ Stress: Impact of Dyadic Coping on Relationship Satisfaction January 2016 (has links) abstract: Intercultural couples -partners from two different countries- may face increased levels of stress within their relationship (internal stress). Internal stress can negatively impact relationship satisfaction, whereas developing healthy ways to cope (dyadic coping; DC) can lower stress levels and improve relationship satisfaction (e.g., Bodenmann, 2005). Specifically, it may be important for partners to perceive that their partner as supporting them during times of stress through engaging in DC. This study examined whether intercultural couples experience internal stress and what effects, if any, perceived partner engagement in DC had on their reported relationship satisfaction. Cross-sectional data was gathered from 85 couples and was analyzed using Actor-Partner Interdependence Models (APIMs; Kenny & Cook, 1999). Separate APIMs were conducted to examine the association between the independent variables (perceived partner engagement in: positive DC, negative DC, delegated DC, and supportive DC) and the outcome variables of internal stress and relationship satisfaction, while controlling for years each partner lived in their country of birth, average and differences on identification with individualism-collectivism values and behaviors, and if partners did or did not identify as the same race and/or ethnicity. Additionally, APIMs of internal stress on relationship as moderated by perceived partner positive and negative DC were conducted. Results showed significant associations of all independent variables on internal stress and relationship satisfaction. There were no signification interactions between internal stress and DC on relationship satisfaction. Implications for relationship researchers and mental health professionals working with intercultural couples are discussed. / Dissertation/Thesis / Masters Thesis Counseling 2016 Counseling psychology Dyadic Coping Dyadic Data Intercultural Couples Internal Stress Relationship Satisfaction Romantic Relationships
8	Investigation of grain size and shape effects on crystal plasticity by dislocation dynamics simulations / Exploration des effets de la taille et de la forme des grains sur la plasticité cristalline par simulations de dynamique des dislocations Jiang, Maoyuan 04 June 2019 (has links) Des simulations de dynamique de dislocation (DD) sont utilisées pour l’étude de l'effet Hall-Petch (HP) et des contraintes internes à long-portée induites par les hétérogénéités de déformation dans les matériaux polycristallins.L'effet HP est reproduit avec succès grâce à des simulations de DD réalisées sur de simples agrégats polycristallins périodiques composés de 1 ou de 4 grains. De plus, l'influence de la forme des grains a été explorée en simulant des grains avec différents rapports d'aspect. Une loi généralisée de HP est proposée pour quantifier l'influence de la morphologie du grain en définissant une taille de grain effective. La valeur moyenne de la constante HP $K$ calculée avec différentes orientations cristallines à faible déformation est proche des valeurs expérimentales.Les dislocations stockées pendant la déformation sont principalement localisées à proximité des joints de grain et peuvent être traitées comme une distribution surfacique de dislocations. Nous avons utilisé des simulations DD pour calculer les contraintes associées aux parois de dislocations de différentes hauteurs, longueurs densités et caractères. Dans tous les cas, la contrainte est proportionnelle à la densité surfacique de dislocations géométriquement nécessaires (GNDs) et sa variation est capturée par un ensemble d'équations empiriques simples. Une prévision de contraintes à long-portée dans les grains est réalisée en sommant les contributions des GNDs accumulées de part et d’autre des joints de grains.L'augmentation de la contrainte interne liée au stockage de GNDs est linéaire avec la déformation plastique et est indépendante de la taille des grains. L'effet de taille observé dans les simulations de DD est attribué au seuil de déformation plastique, contrôlé par deux mécanismes concurrents : la contrainte critique de multiplication des sources et la contrainte critique de franchissement de la forêt. En raison de la localisation de la déformation dans les matériaux à gros grains, le modèle d’empilement des dislocations doit être utilisé pour prédire la contrainte critique dans ce cas. En superposant cette propriété aux analyses que nous avons fait à partir de simulations de DD dans le cas d'une déformation homogène, l'effet HP est justifié pour une large gamme de tailles de grains. / Dislocation Dynamics (DD) simulations are used to investigate the Hall-Petch (HP) effect and back stresses induced by grain boundaries (GB) in polycrystalline materials.The HP effect is successfully reproduced with DD simulations in simple periodic polycrystalline aggregates composed of 1 or 4 grains. In addition, the influence of grain shape was explored by simulating grains with different aspect ratios. A generalized HP law is proposed to quantify the influence of the grain morphology by defining an effective grain size. The average value of the HP constant K calculated with different crystal orientations at low strain is close to the experimental values.The dislocations stored during deformation are mainly located at GB and can be dealt with as a surface distribution of Geometrically Necessary Dislocations (GNDs). We used DD simulations to compute the back stresses induced by finite dislocation walls of different height, width, density and character. In all cases, back stresses are found proportional to the surface density and their spatial variations can be captured using a set of simple empirical equations. The back stress calculation inside grains is achieved by adding the contributions of GNDs accumulated at each GB facet.These back stresses are found to increase linearly with plastic strain and are independent of the grain size. The observed size effect in DD simulations is attributed to the threshold of plastic deformation, controlled by two competing mechanisms: the activation of dislocation sources and forest strengthening. Due to strain localization in coarse-grained materials, the pile-up model is used to predict the critical stress. By superposing such property to the analysis we made from DD simulations in the case of homogeneous deformation, the HP effect is justified for a wide range of grain sizes. Effet de taille Dynamique des dislocations Plasticité cristalline Contraintes internes Size effect Dislocation dynamics Crystal plasticity Internal stress
9	A diffusion-viscous analysis and experimental verification of the drying behavior in nanosilver-enabled low-temperature joining technique Xiao, Kewei 23 January 2014 (has links) The low-temperature joining technique (LTJT) by silver sintering is being implemented by major manufacturers of power electronics devices and modules for bonding power semiconductor chips. A common die-attach material used with LTJT is a silver paste consisting of silver powder (micron- or nano-size particles) mixed in organic solvent and binder formulation. It is believed that the drying of the paste during the bonding process plays a critical role in determining the quality of the sintered bond-line. In this study, a model based on the diffusion of solvent molecules and viscous mechanics of the paste was introduced to determine the stress and strain states of the silver bond-line. A numerical simulation algorithm of the model was developed and coded in the C++ programming language. The numerical simulation allows determination of the time-dependent physical properties of the silver bond-line as the paste is being dried with a heating profile. The properties studied were solvent concentration, weight loss, shrinkage, stress, and strain. The stress is the cause of cracks in the bond-line and bond-line delamination. The simulated results were verified by complementary experiments in which the formation of cracks in bond-line and interface delamination was observed during the pressure-free drying of a die-attach nanosilver paste. Furthermore, the important drying parameters, such as drying pressure, low temperature drying time and temperature ramp rate of nanosilver LTJT process, are experimentally studied and analyzed with the numerical simulation. The simulated results were consistent with the experimental findings that the quality of sintered silver bond-line increases with increasing external drying pressure, with increasing low temperature drying time, and with decreasing temperature ramp rate. The insight offered by this modeling study can be used to optimize the process profile that enable pressure-free, low-temperature sintering of the die-attach material to significantly lower the cost of implementing the LTJT in manufacturing. / Ph. D. low-temperature joining drying of silver paste internal stress bond-line defect formation
10	Flexural Analysis and Composite Behavior of Precast Concrete Sandwich Panel Naji, Behnam January 2012 (has links) No description available. Civil Engineering Mechanical Engineering PCSP deflection equation composite behavior moment internal stress shear modulus of the core

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