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Examining Predictors of Change in Emotionally Focused Couples TherapyDalgleish, Tracy L. January 2013 (has links)
Emotionally Focused Couple Therapy (EFT; Johnson, 2004) is an empirically validated approach to couple therapy that uses attachment theory to understand the needs and emotions of romantic partners. In EFT, relationship distress is conceptualized as resulting from negative affect, emotional disconnection, and unmet attachment needs. Although EFT is recognized as one of the most researched and effective approaches to couple therapy, little research has examined theoretically related characteristics of couples to changes in marital satisfaction throughout EFT. The present doctoral thesis examined this area of literature. Thirty-two couples were provided approximately 21 sessions of EFT. The goal of the first study was to identify intake characteristics related to change in marital satisfaction over the course of EFT. Couples completed self-report measures of marital satisfaction, attachment security, relationship trust, and emotional control at pre- and post-therapy and after each therapy session. Individuals higher on self-report attachment anxiety and higher levels of emotional control had greater change in marital satisfaction over the course of EFT. The goal of the second study was to examine intake levels of attachment security and its relationship to the occurrence of the blamer-softening event, a key change event in EFT, and changes in marital satisfaction. Results indicated that the occurrence of a blamer-softening event significantly predicted positive changes in marital satisfaction. Results also suggested that the occurrence of a softening event significantly moderated the relationship between attachment avoidance at intake and change in marital satisfaction from pre- to post-therapy. For couples who completed a blamer-softening event, partners with lower levels of attachment avoidance were more likely to have positive changes in marital satisfaction. However, this relationship was not evident for attachment anxiety. Overall, results from this thesis suggest that attachment security is a key characteristic of couple partners for therapists to consider when implementing EFT. Therapists may benefit from assessing attachment security at the start of therapy to help inform them of the emotion regulating strategies used by couple partners. This information may help therapists to tailor specific interventions such that couples may begin to develop more secure attachment bonds.
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Dynamic Control of Hydrogel Properties via Enzymatic ReactionsMoore, Dustin M. 05 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Dynamic changes to the extracellular matrix (ECM) impact many cell fate pro-
cesses. The ECM can experience changes in sti ness as well as changes in composi-
tion in response to injury, development, and diseases. To better understand the role
that these dynamic processes have on the cells residing within the environment, re-
searchers have turned towards 4-dimensional (4D) hydrogel designs. These 4D hydro-
gels re-capitulate not only 3-dimensional (3D) matrix architectures, but also temporal
changes in the physicochemical properties. The goal of this thesis was to design a
unify chemistry (i.e., Sortase A (SrtA)-mediated transpeptidation) for dynamic tun-
ing hydrogel sti ness and the presence of bioactive ligands. The rst objective was
to establish a tunable and cytocompatible enzymatic scheme for softening cell-laden
hydrogels. Brie
y, the e ects of SrtA-mediated matrix cleavage were investigated us-
ing poly(ethylene glycol) (PEG)-peptide hydrogels crosslinked by SrtA-sensitive and
insensitive peptides. Initially, the e ects of various parameters with respect to cat-
alytic reactions of SrtA were characterized rheologically, including enzyme and sub-
strate concentrations, macromer content, peptide composition, and treatment time.
Gel moduli pre- and post-enzyme treatment were measured to verify SrtA-mediated
hydrogel softening. The cytocompatibility of SrtA-mediated gel softening system was
investigated using human mesenchymal stem cell (hMSC). Upon treatment with SrtA
and an oligoglycine substrate, encapsulated hMSCs exhibited extensive spreading in
comparison to those within statically sti matrices. The second objective was to es-
tablish a reversible ligand exchange system utilizing SrtA-mediated transpeptidation.
SrtA-sensitive pendant ligands were immobilized within PEG hydrogels, which were treated with SrtA and an oligoglycine substrate to a ord tunable removal of the pen-
dant ligand. Through measurement of the liberated pendant peptide concentration,
it was found that higher concentrations of SrtA or extending treatment times led
to higher ligand removal e ciency. Finally, the e ect of peptide ligand removal on
cell behaviors were evaluated using NIH 3T3 broblasts. Fibroblasts were culture
both on and within hydrogels containing SrtA-cleavable cell adhesion peptide. After
treatment, both conditions led to a decrease in broblast spreading in comparison
to non-treated gels. Overall, the utility of SrtA as versatile agent for controlling the
mechanical properties and the presence of biologically active components within a
hydrogel system was demonstrated. These systems could be further explored with natural-based materials to better mimic the physiological environment experienced
by cells.
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Microstructure and Mechanical Properties of the Fusion and Heat-Affected Zones of a Laser Welded DP780 SteelSmith, Heather January 2015 (has links)
Bead-on-plate laser welds were made on an industrially produced DP780 steel to determine the effect of normalized welding heat input on the microstructure and mechanical properties within the weld fusion zone (FZ) and heat affected zone (HAZ) with reference to the base material (BM) mechanical properties. Normalized welding heat input was calculated using an established model from the literature utilizing measurements from the weld cross-section microstructures along with known materials properties. Microhardness profiles and optical microscopy were employed to evaluate materials properties and microstructural changes across the various microstructural zones of each weld. The mechanical properties of the welds were evaluated globally through standard ASTM tensile specimens as well as through a series of specialized mechanical testing sample geometries which examined the properties of individual microstructural zones. These specialized sample geometries included non-standard uniaxial and plain strain tension where effective stress and effective strains were used to compare the mechanical properties across samples.
It was determined that there was a good correlation between ASTM standard samples and the specialized sample geometries employed in this study and that the UTS and YS values obtained in both cases were comparable. Sigmoidal decay behaviour was observed in the UTS and YS with increasing heat input for both the FZ and HAZ of all welds. It was found that welds with heat inputs greater than 60 J/mm2 had both a UTS and YS which were significantly depressed in the FZ and HAZ when compared to the base material values. Conversely, welds with heat inputs below 36.3 J/mm2 were found to have a UTS and YS in both the FZ and HAZ microstructural zones which were above the values determined for the BM. When global weld properties were tested, it was found that welds with a heat input greater than 60.0 J/mm2 failed within the HAZ while welds with heat inputs below 36.3 J/mm2 failed within the BM. It has been shown that there is a significant correlation between the heat inputs of laser welded DP steels and both the mechanical properties and microstructural features of the various microstructural zones as well as the location of failure during weld tensile testing. It has also been demonstrated that the mechanical properties of weld microstructural zones can be qualitatively evaluated using specialized tensile testing geometries. / Thesis / Master of Applied Science (MASc)
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Shear Strength Behavior of Unsaturated Soils During Strain-SofteningYang, Xiuhan 13 February 2023 (has links)
The shear stress in an unsaturated soil increases rapidly with limited shear strain to a peak value and then drops gradually with a further increase in the shear strain until a residual value is reached. In other words, there is a significant strain-softening behavior under large shear deformation. A variety of geotechnical structures (e.g., slopes, foundations, retaining walls and piles) associated with unsaturated soils typically undergo a large progressive deformation prior to reaching failure conditions due to the influence of environmental factors (e.g., rainfall infiltration and wetting-drying cycles). As a result, the shear strength of soils in sliding zones typically reduces from a peak to a residual value with the progressive development of large shear deformation, while the shear strength of soils in other zones are still at the peak level. In other words, in many scenarios the strain-softening behavior of unsaturated soils can significantly influence the mechanical behavior of geo-structures. Therefore, a thorough understanding of the shear strength behavior of unsaturated soils during strain-softening is required to reliably interpret the mechanical behavior of geo-structures that undergo large shear deformation.
Significant advances have been made during the last thirty years to understand and model the strain-softening behavior of unsaturated soils. Most of these studies however focus on the strain-softening behavior within a relatively small shear deformation due to the limitations of the experimental apparatuses. Only limited experimental studies under large shear deformation were reported based on the modified suction-controlled ring shear apparatus. Therefore, more investigations are still required to provide a comprehensive understanding of the shear strength behavior of unsaturated soils during strain-softening under large shear deformation.
Studies presented in this thesis are directed towards investigating the shear strength behavior of unsaturated soils during strain-softening and its application in geotechnical engineering practice. The following studies have been conducted:
(i) A state-of-the-art review of the strain-softening behavior of unsaturated soils published in the literature during the past three decades is summarized. The physical mechanisms and modelling methods of the strain-softening behavior and the peak, critical and residual shear strength of unsaturated soils are investigated.
(ii) A disturbed state concept model is proposed to predict the variation of shear stress in unsaturated soils during strain-softening process under drained condition. Five sets of experimental data gathered from the literature on unsaturated soils varying from coarse- to fine-grained soils are used to verify the proposed model. The proposed model can provide reasonable predictions for the strain-softening stress-strain relationships of various types of unsaturated soils. The model is simple in concept and all the required parameters can be obtained from conventional saturated and unsaturated shearing tests and pressure plate tests.
(iii) Two sets of suction-controlled multistage ring shear tests are conducted on unsaturated SP-SM soil and Indian Head till (IHT), respectively. The variation of the shear stress, void ratio, and water content of specimens during shearing (the shear displacement reaches 100 mm) under multi levels of net normal stress and matric suction are described and discussed. The influence of matric suction and net normal stress on the residual shear strength envelops of unsaturated soils are critically discussed.
(iv) A model for predicting the residual shear strength for a wide range of unsaturated soils comprising coarse- to fine-grained soils is developed in terms of two stress state variables (i.e., the net normal stress and matric suction) by using the soil water characteristic curve as a tool. The model is formulated and validated based on experimental data in a series of suction-controlled ring shear tests using the axis-translation technique, including the two sets of tests (SP-SM and IHT) conducted in this research and another three sets of tests (SM, SC-SM and CH) gathered from the literature. The fitting parameters are related to the plasticity index (Iₚ); thus, only four basic parameters (i.e., cᵣ', φᵣ', Sᵣ and Iₚ) are included in this approach.
(v) A series of slope stability analyses of a landslide in unsaturated condition are conducted using Geoslope software based on the peak and residual shear strength parameters. The analyses results highlight the role of residual shear strength in the slope stability of unsaturated soils.
In summary, the mechanical behavior of unsaturated soils under large shear deformation is comprehensively investigated in this thesis. The experimental results of the suction-controlled ring shear tests reported in this research contribute towards understanding the fundamental shear strength behavior of unsaturated soils during strain-softening under large shear deformation. The models proposed in this research provide simple tools to predict the shear strength of unsaturated soils under different levels of shear deformation.
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Defining the mechanical characteristics of porcine brain tissue subject to cyclic, compressive loadingSebastian, Kali 01 May 2020 (has links)
In recent years, repetitive traumatic brain injuries have been linked to the progressive neurodegenerative disorder termed chronic traumatic encephalopathy. However, the mechanical characteristics of brain tissue exposed to repetitive loading still lack understanding. This research evaluated the response of porcine brain tissue undergoing cyclic, compressive loading in reference to three impact parameters: cycle number (N25, N50, N100, N150, and N200), strain level (15, 30, and 40%), and strain rate (0.00625, 0.025, 0.10, and 1.0/s). Following mechanical testing, tissue samples were processed for hematoxylin and eosin (H&E) staining. Stress values, hysteresis energy, and decreases in hysteresis energy for all parameters were compared. The data suggest that microstructural brain tissue damage is highly dependent on strain level and cycle number, whereas strain rate did not appear to cause permanent damage in the quasi-static range applied. The onset of permanent microstructural tissue damage may relate to movement of fluid molecules within the tissue.
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Enhanced Removal of Natural Organic Matter During Lime-Soda SofteningBob, Mustafa M. 19 March 2003 (has links)
No description available.
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Heat-Affected Zone Softening Kinetics in Dual-Phase and Martensitic SteelsBiro, Elliot 04 1900 (has links)
<p>Advanced high strength steels, such as dual-phase and martensitic steels, are increasingly being used by automakers to decrease the thickness of steel sheet used in parts without sacrificing part strength. When welded, the martensite within the dual-phase and martensitic steel microstructures tempers, reducing the heat-affected zone (HAZ) hardness compared to the base material, locally reducing strength. This process is known as HAZ softening. HAZ softening has been well studied; however, the kinetics of this process has not been quantified and the processes responsible for HAZ softening have not been examined. This thesis investigated both of these topics.</p> <p>HAZ softening was modelled using the Johnson-Mehl-Avrami-Kolmogorov (JMAK) equation. As the thermal profile during welding is non-isothermal, the effects of temperature and time on steel tempering kinetics could not be separated by examining post-welded properties. The effects of tempering temperature and time were separated through a series rapid isothermal tempering experiments. Hardness data from these experiments allowed the HAZ softening rate to be empirically quantified through fitting the JMAK equation. This material model was then validated by predicting HAZ softening in laser and resistance spot welds. Although the fitted JMAK constants could be used to predict post-weld HAZ hardness, they did not agree with the classic literature values associated with martensite tempering.</p> <p>To understand why the JMAK coefficients did not match those of the classic martensite tempering literature, the softening data from one of the martensitic steels was re-examined. This study revealed that the softening process was a combination of two processes: carbide nucleation and carbide coarsening. The activation energies calculated for each process matched the classic literature values. Carbide coarsening dominated during tempering, which had a non-linear relation with change in hardness. The relationship between carbide coarsening and hardness was responsible for the softening kinetics measured from the rapid tempering experiments.</p> / Doctor of Philosophy (PhD)
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Journalistik och plattformslogik : En analys av svenska nyhetsmediers rapportering på olika plattformarJosefsson, Henny January 2024 (has links)
Digitaliseringen har omförhandlat vilkoren för journalistiken och hur den på förmedlar samhällsnyttig information till medborgarna i en demokrati. Uppsatsens övergripande syfte är att beskriva i vilken utsträckning och hur centrala svenska nyhetsmedier anpassar sin nyhetsrapportering på sociala medier efter plattformslogik. Detta har gjorts utifrån begreppet “uppmjukning av sociala nyheter” (social news softening) som definierats av Klein m.fl. 2023. Studiens kvantitativa del utgörs av en sammanställning av nyhetsartiklarnas ämne, avseende distinktionen mellan hårda och mjuka nyhetsämnnen. Materialet för denna analys består av inlägg från Dagens Nyheter och SVT Nyheter på Facebook och Instagram. Den kvalitativa delen består av en innehållsanalys av utvalda nyhetsartiklar och inlägg från Dagens Nyheter och SVT Nyheter på respektive konto på Instagram, Facebook samt på mediernas egna webbsidor. Studiens kvantitativa resultat visar att både Dagens Nyheter och SVT Nyheters nyhetsrapportering inför det svenska riksdagsvalet 2022 i huvudsak består av hårda nyhetsämnen. Det kvalitativa resultatet visar på väldigt få och svaga tendenser på uppmjukning av sociala nyheter enligt Klein m.fl.:s konceptualisering.
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Passive Earth Pressures on a Pile Cap with a Dense Sand BackfillMarsh, Robert Ashall 15 December 2009 (has links) (PDF)
Pile groups are often used to provide support for structures. Capping a pile group further adds to the system's resistance due to the passive earth pressure from surrounding backfill. While ultimate passive earth pressure under static loading conditions can be readily calculated using several different theories, the effects of cyclic and dynamic loading on the passive earth pressure response are less understood. Data derived from the full-scale testing of a pile cap system with a densely compacted sand backfill under static, cyclic, and dynamic loadings was analyzed with particular focus on soil pressures measured directly using pressure plates. Based on the testing and analyses, it was observed that under slow, cyclic loading, the backfill stiffness was relatively constant. Under faster, dynamic loading, the observed backfill stiffness decreased in a relatively linear fashion. During cyclic and dynamic loading, the pile cap gradually developed a residual offset from its initial position, accompanied by a reduction in backfill force. While the pile cap and backfill appeared to move integrally during static and cyclic loadings, during dynamic loading the backfill exhibited out-of-phase movement relative to the pile cap. Observed losses in backfill contact force were associated with both cyclic softening and dynamic out-of-phase effects. Force losses due to dynamic loading increased with increasing frequency (which corresponded to larger displacements). Losses due to dynamic loading were offset somewhat by increases in peak force due to damping. The increase in contact force due to damping was observed to be relatively proportional to increasing frequency. When quantifying passive earth forces with cyclic/dynamic losses without damping, the Mononobe-Okabe (M-O) equation with a 0.75 or 0.8 multiplier applied to the peak ground acceleration can be used to obtain a reasonable estimate of the force. When including increases in resistance due to damping, a 0.6 multiplier can similarly be used.
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Stress distribution within geosynthetic-reinforced soil structuresYang, Kuo-hsin 23 October 2009 (has links)
This dissertation evaluates the behavior of Geosynthetic-Reinforced Soil (GRS)
retaining structures under various soil stress states, with specific interest in the
development and distribution of soil and reinforcement stresses within these structures.
The stress distribution within the GRS structures is the basis of much of the industry’s
current design. Unfortunately, the stress information is often not directly accessible
through most of current physical testing and full-scale monitoring methods. Numerical
simulations like the finite element method have provided good predictions of
conservatively designed GRS structures under working stress conditions. They have provided little insight, however, into the stress information under large soil strain
conditions. This is because in most soil constitutive models the post-peak behavior of
soils is not well represented. Also, appropriate numerical procedures are not generally
available in finite element codes, the codes used in geotechnical applications. Such
procedures are crucial to properly evaluating comparatively flexible structures like GRS
structures. Consequently, this study tries to integrate newly developed numerical procedures
to improve the prediction of performance of GRS structures under large soil strain
conditions. There are three specific objectives: 1) to develop a new softening soil model
for modeling the soil’s post-peak behavior; 2) to implement a stress integration algorithm,
modified forward Euler method with error control, for obtaining better stress integration
results; and 3) to implement a nonlinear reinforcement model for representing the
nonlinear behavior of reinforcements under large strains. The numerical implementations
were made into a finite element research code, named Nonlinear Analysis of
Geotechnical Problems (ANLOG). The updated finite element model was validated
against actual measurement data from centrifuge testing on GRS slopes (under both
working stress and failure conditions).
Examined here is the soil and reinforcement stress information. This information
was obtained from validated finite element simulations under various stress conditions.
An understanding of the actual developed soil and reinforcement stresses offers important
insights into the basis of design (e.g., examining in current design guidelines the design
methods of internal stability). Such understanding also clarifies some controversial
issues in current design. This dissertation specifically addresses the following issues: 1)
the evolution of stresses and strains along failure surface; 2) soil strength properties (e.g.,
peak or residual shear strength) that govern the stability of GRS structures; 3) the
mobilization of reinforcement tensions.
The numerical result describes the stress response by evaluating the development
of soil stress level S. This level is defined as the ratio of the current mobilized soil shear
strength to the peak soil shear strength. As loading increases, areas of high stress levels
are developed and propagated along the potential failure surface. After the stress levels
reach unity (i.e., soil reaches its peak strength), the beginning of softening of soil strength is observed at both the top and toe of the slope. Afterward, the zones undergoing soil
softening are linked, forming a band through the entire structure (i.e., a fully developed
failure surface). Once the band has formed and there are a few loading increments, the
system soon reaches, depending on the tensile strength of the reinforcements, instability.
The numerical results also show that the failure surface corresponds to the locus of
intense soil strains and the peak reinforcement strain at each reinforcement layer. What
dominates the stability of GRS structures is the soil peak strength before the completed
linkage of soil-softening regions. Afterward, the stability of GRS structures is mainly
sustained by the soil shear strength in the post-peak region and the tensile strength of
reinforcements. It was also observed that the mobilization of reinforcement tensions is
disproportional to the mobilization of soil strength. Tension in the reinforcements is
barely mobilized before soil along the failure surface first reaches its peak shear strength.
When the average mobilization of soil shear strength along the potential failure surface
exceeds approximately 95% of its peak strength, the reinforcement tensions start to be
rapidly mobilized. Even so, when the average mobilization of soil strength reaches 100%
of its peak shear strength, still over 30% of average reinforcement strength has not yet
been mobilized. The results were used to explain important aspects of the current design
methods (i.e., earth pressure method and limit equilibrium analysis) that result in conservatively designed GRS structures. / text
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