Gender ideology: impact on dual-career couples' role strain, marital satisfaction, and life satisfaction

King, Jennifer Jean

12 April 2006

With dual-career couples comprising the most common family type, it is important for mental health professionals, employers, and policy makers to understand the unique challenges of this population (Haddock et al., 2001; Saginak & Saginak, 2005.) Numerous researchers have studied the consequences of family and work role strain for dual-career couples. However, when dual-career couples are able to share responsibilities and negotiate degendered roles they experience the benefits of dual-career couples. The literature clearly supports the importance of egalitarian roles for marital satisfaction and life satisfaction of dual-career couples. While researchers have studied social role strain, gender role strain, marital satisfaction, and life satisfaction and discussed the importance of degendered roles and responsibilities for dual-career couples, no studies have examined gender ideology. Saginak and Saginak (2005) called for researchers to investigate how gender ideologies and the gender socialization process perpetuate the challenges faced by dual-career couples in balancing work and family. This study investigated the associations between gender ideology and gender role strain, job-family role strain, marital satisfaction, and life satisfaction among 70 individual members of dual-career couples. A multivariate analysis of variance was utilized to investigate the relationship between gender ideology and the criterion measures. Gender ideology was partially associated with gender role strain with the androgynous gender ideology group scoring significantly lower on gender role strain than the masculine or undifferentiated gender ideology groups but not significantly lower than the feminine gender ideology group. Gender ideology was not associated with job-family role strain or marital satisfaction. In addition, gender ideology was also partially associated with life satisfaction with the androgynous gender ideology group scoring significantly higher on quality of life than the masculine or undifferentiated gender ideology groups but not significantly higher than the feminine gender ideology group. Thus, the current study indicates there are partial associations between gender ideology and gender role strain and life satisfaction for dual-career couples. Mental health professionals, employers, and policy makers working with dual-career couples should assess the socially constructed gender norms and expectations internalized by individuals into a gender ideology as the possible source of challenges experienced by the dual-career couple.

Dual-Career

Gender Ideology

Role Strain

Marital Satisfaction

Life Satisfaction

Quantifying the strain response in the rat tibia during simulated resistance training used as a disuse countermeasure

Jeffery, Jay Melvin

10 October 2008

Disuse of weight bearing bones has been shown to cause bone loss. This poses a health concern for people exposed to microgravity, such as astronauts. Animal studies are used to study factors related to bone loss and countermeasures to prevent bone loss. This study used a hindlimb unloaded (HU) rat model to simulate microgravity and a muscle stimulation countermeasure to simulate resistive exercise. Uniaxial strain gages were implanted on the antero-medial aspect of the proximal tibia to measure the mechanical strain during a typical exercise session. In a separate but parallel study, the exercise was shown to be an effective countermeasure to disuse related bone loss. The current study sought to understand the loading of the bone during the exercise. To determine if the strain response changes during a protocol using this countermeasure, strains were measured on a group of weight bearing animals and a group that were hind limb unloaded and received the countermeasure for 21 days. Strain magnitudes and rates were considered and related to torques at the ankle joint. No significant differences in strain magnitudes were noted between the baseline control group and the hindlimb unloaded group that received the countermeasure. The two kinds of contractions used in an exercise session are isometric and eccentric. The isometric contractions are used to adjust the stimulation equipment for the eccentric contractions, which constitute the exercise. Peak strain levels during the isometric contractions ranged from 900 to 2200 microstrain while the eccentric were 38% lower and ranged from 600 to 1400. Eccentric strain rates were 62% lower than the isometric contractions strain rates. These results indicate that the strain environment during the isometric contractions may be causing more of the osteogenic response than the eccentric contractions, which have previously been thought to be the primary part of the countermeasure.

Strain

Rat

Disuse

Bone

Tibia

Mechanics

Biomechanics

Exercise

Muscle stimualtion

Analysis of Plasticity and Shear Band Deformation Mechanism in Bulk Metallic Glasses and Composites

Chen, Hai-min

16 November 2009

On the toughening of bulk metallic glasses (BMGs), successful results in the phase-separated Zr63.8Ni16.2Cu15Al5 BMG have achieved compressive ductility over 15% through the computational-thermodynamic approach. In this study, the phase-separated Zr63.8Ni16.2Cu15Al5 BMG was compressed to nominal strains of 3%, 7%, and 10% at low strain rates (~10-4 s-1) and the results demonstrated that the BMG exhibited apparent uniform deformation initially, followed by visible local shear bands development. Afterwards, a single shear along the principal shear plane was soon developed and mainly dominated the whole deformation process. The principal shear contributed more than 2/3 of the overall plastic strain until failure. It was also found that the local shear strain varied along the principal shear plane and decreased monotonically from the shear band initiation site. Subsequently, in-situ compression experiments were conducted to monitor the change of sample shape during deformation in order to properly correlate with the stress-strain curve. The observed images showed that there was a one-to-one correspondence between the intermittent sample sliding and flow serration in the plastic region of stress-strain curve. Further investigations on flow serration were conducted on the Pd40Ni40P20 BMG through the compression experiments equipped with high-sensitivity strain gauges directly attached to two opposite sides of the test sample. There was an accompanied displacement burst when a shear band starts to propagate during deformation and this displacement burst would be accurately captured by the high-sensitivity strain gauges. Based on the displacement-time profile for one serration, shear-band propagating speed can be estimated and found to be insensitive to the applied strain rates (or the applied crosshead speeds). The disappearance of flow serration at high strain rates should be a result that the signal of displacement burst was overwhelmed by the applied strain rate. Using the shear strain rate data, the measured viscosity within a propagating shear band was found to be relatively low, which is in similar to the viscosity values reported in the supercooled liquid region during homogeneous deformation. In comparison with shear band propagation in the brittle Mg58Cu31Y6Nd5 and Au49Ag5.5Pd2.3Cu26.9Si16.3, moderately ductile Cu50Zr43Al7 and Pd40Ni40P20, and highly ductile phased-separated Zr63.8Ni16.2Cu15Al5 systems, the ductility of BMGs appears to be closely related to the dynamics during shear band propagation. The more ductile in nature the metallic glass is, the slower the shear band propagating speed would become. We also made attempts to investigate the shear band propagation in the porous Mo particles reinforced Mg58Cu28.5Gd11Ag2.5 bulk metallic glass composites (BMGCs) with up to 10% compressive failure strain. It was found that flow serration was absent in the stress-strain curve. Using high-sensitivity strain gauges, no distinct displacement burst was detected in the displacement-time profile. The diappearance of flow serration for the current porous Mo particles reinforced Mg58Cu28.5Gd11Ag2.5 BMGC is apparently associated with the lack of long-range shear band propagagtion. By employing the approach of separating the homogeneous amorphous matrix into many individual compartments, only short-range shear band propgagation is possible in the current Mg-based BMGC. An effective free spacing considering the spacing between two porous Mo particles and porous Mo particle size was applied to interpret the development of shear band propagation and is a useful indicator for the design of BMGC with high ductility.

shear band propagation

plastic strain

bulk metallic glasses

flow serration

Manufacturihng of heavy rings and large copper canisters by plastic deformation

Ssemakula, Hamzah

January 2003

<p>Plastic deformation processes transform material fromas-received state to products meeting certain requirements inproperties, microstructure and shape. To achieve thistransformation, the relationship between material response andprocess conditions should be understood. This is usuallycomplicated by the complex conditions describing the actualprocess. Numerous techniques including empirical, physical,analytical and numerical can be employed.</p><p>In this thesis, numerical technique supported by lab- andfull-scale experiments has been employed to analyse the formingparameters. The first part of the thesis is focused on the useof such parameters to predict occurrence of material poresduring manufacturing of bearing rings. The second part dealswith the influence of forming parameters on the grain sizeduring fabrication of large copper canisters for encapsulationof nuclear waste. The primary task has been to study with thehelp of commercial FE-codes the magnitude and distribution offorming parameters such as accumulated effective strain,temperature, instantaneous hydrostatic pressure and materialflow at different stages of the forming process. In the firstpart, two types of ring manufacturing routes, which result inpore free and pore loaded rings are studied and compared.Material elements located in different areas of the workpiecehave been traced throughout the process. Results of theaccumulated strain and instant hydrostatic pressure have beenanalysed and presented in pressure-strain space. It’sassumed that high hydrostatic pressures together with higheffective strains are favourable for pore closure. Area of theworkpiece with unfavourable parameters have been identified andcompared with ultrasonic test results. Good agreement has beenobtained. Based on the results of this analysis, a new conceptfor avoiding pores in manufacturing of yet heavier rings hasbeen presented. The concept proposes a lighter upsetting in theinitial stage of the process and a more efficient piercingwhich results in higher hydrostatic pressure and bigger andbetter distributed effective strain.</p><p>In the second part of the thesis, the influence of formingparameters such as effective strain and temperature on thefinal grain size of the product has been studied in laboratoryscale. As-cast billets of cylindrical shape were extruded atdifferent temperatures and reductions. It has been shown thatthe grain size in the final product should be small in order toenable ultrasonic tests and to guarantee resistance towardscreep and corrosion. Simulations for different materialelements located at different distances from the axis ofsymmetry of the initial cylindrical workpiece have been carriedout. In this way, the parameters describing the deformationhistory of the elements have been determined as functions oftime. Experimentally obtained pre- and post deformation grainsize in the corresponding locations of the material weredetermined. It’s concluded that low temperature coupledwith high effective strain are conducive for obtaining a smallgrain size. Based on the beneficial conditions for extrusion ofcopper, a more detailed FE-analysis of a full-scale industrialprocess is carried out. A coarse-grained cast ingot of purecopper is heated and by upset forging formed into a cylinder,which is then punched into a hollow blank for subsequentextrusion. The blank is extruded over a mandrel through a45-degree semi-angle die. Accumulated effective strain andtemperatureas functions of the tubular wall thickness havebeen studied at five different locations along the tubularaxis. Forming load requirement as function of tool displacementfor each stage of the process has been determined. Strain andtemperature levels obtained have been related to the grain sizeinterval obtained in the earlier work. It has been concludedthat the levels reached are within the interval that ensures asmall grain size. A similar analysis has been carried out forforging of large copper lids and bottoms. Die designmodifications to improve the grain size in the lid and tooptimise the forging process with respect to forging load andmaterial yield have been proposed. A method requiring a smallforging load for fabrication of the lids has been analysed</p><p><b>Keywords:</b><i>Pores; grain size; low forging load; effective strain;temperature; hydrostatic pressure; extrusion; forging;canister; lid; rings</i></p>

pores

grain size

low forginnig load

effective strain

Lastcells applikation : Verktyg för montering av trådtöjningsgivare i lastcell

Stumle, Joakim

January 2007

<p>Ett verktyg för applicering av trådtöjningsgivare har tagits fram på uppdrag av AED AB i Växjö. Verktyget skall användas för färdigställning/slutmontering av lastceller som i sin tur skall användas till att mäta vilka krafter som påverkar en skogsmaskin när denna lastas med sin givna maxlast. Verktyget skall föras in i ett 25 mm brett hål där det skall hålla fast och lägga tryck på fyra trådtöjningsgivare, en i vardera riktning, vilka bestrykts med lim. Verktyget skall hålla ett tryck på tre till fyra kiloPond medan lastcellen värms till 150° C då limmet härdar. Verktyget består av fyra ben, ett i vardera riktning. De är ledande i en änden. Andra änden på benen är avfasad och bildar en öppning. När en kula trycker mot benens avfasade ytor expanderar dem utåt och trycker därmed den limbestrukna trådtöjningsgivaren mot hålets vägg.</p> / <p>A tool for the application of strain gauges have been constructed by the commission of AED AB in Växjö. The tool shall be used for the assembling of loadcells which then will be used for measuring forces that affects a loggingmachinery when loaded with its maximum load. The tool shall be inserted in a 25 mm wide hole where it is supposed to hold and apply load to four strain gauges, one in each direction, which has been smeared with glue. The tool shall maintain a pressure of three to four kiloPond while the loadcell is heated to 150 C until the glue has hardened. It consists of four legs with a joint in one end and a slant surface by the other. When a ball is pushed against the slant surfaces, the legs will expand and push the glue smeared strain gauges against the wall of the hole.</p>

Loadcell

Strain gauge

Lastcell

Trådtöjningsgivare

Engineering mechanics

Teknisk mekanik

Assessment of hip fracture risk using cross-section strain energy determined from QCT-based finite element model

Kheirollahi Nataj Bisheh, Hossein

12 September 2015

Accurate assessment of hip fracture risk is very important to prevent hip fracture and to monitor the effect of a treatment. A subject-specific QCT-based finite element model was constructed to assess hip fracture risk at the critical locations of femur during the single-leg stance and the sideways fall. The aim of this study was to improve the prediction of hip fracture risk by introducing a more proper failure criterion to more accurately describe bone failure mechanism. Hip fracture risk index was defined using the strain energy criterion, which is able to integrally consider information such as stresses, strains and material properties in bone failure. It was found that the femoral neck and the intertrochanteric region have higher fracture risk than other part of the femur, probably owing to the larger content of cancellous bone in these regions. The study results also suggested that women are more prone to hip fracture than men. The effects of different parameters such as age, body height, weight, and BMI on hip fracture risk were also investigated in this study. The findings in this study have a good agreement with those clinical observations reported in the literature. The main contributions from this study include: (1) introducing an algorithm for hip fracture risk assessment at the critical locations of femur using the strain energy criterion and QCT-based finite element modeling, (2) theoretically more reasonable definition of hip fracture risk index based on the strain energy criterion, and (3) a semi-automatic finite element analysis and automatic calculation of hip fracture risk index at the critical locations of femur using in-house developed computer codes. The proposed hip fracture risk index based on the strain energy criterion will be a promising tool for more accurate assessment of hip fracture risk. However, experimental validation should be conducted before its clinical applications. / October 2015

Coherent scattering in two dimensions: graphene and quantum corrals

Barr, Matthew Christopher

January 2014

Two dimensional electronic materials provide a vibrant area for applying basic quantum mechanics and scattering theory. In quantum corrals, multiple scattering leads to resonances closely approximating eigenstates of an equivalently shaped billiard. We extend the analogy using methods from acoustics to demonstrate that the billiard conception of quantum corrals is a useful one even in wavelength regimes close to corral size. Resonance widths can be described by a simple relationship proportional to the perimeter to area ratio of the enclosure and the average reflection of a classical path. / Physics

Physics

acoustics

graphene

quantum corral

quantum dot

scattering

strain

First-principles atomistic modeling for property prediction in silicon-based materials

Bondi, Robert James

02 February 2011

The power of parallel supercomputing resources has progressed to the point where first-principles calculations involving systems up to 10³ atoms are feasible, allowing ab initio exploration of increasingly complex systems such as amorphous networks, nanostructures, and large defect clusters. Expansion of our fundamental understanding of modified Si-based materials is paramount, as these materials will likely flourish in the foreseeable cost-driven future in diverse micro- and nanotechnologies. Here, density-functional theory calculations within the generalized gradient approximation are applied to refine configurations of Si-based materials generated from Metropolis Monte Carlo simulations and study their resultant structural properties. Particular emphasis is given to the contributions of strain and disorder on the mechanical, optical, and electronic properties of modified Si-based materials in which aspects of compositional variation, phase, strain scheme, morphology, native defect incorporation, and quantum confinement are considered. The simulation strategies discussed are easily extendable to other semiconductor systems. / text

Silicon

Density-functional theory

Strain effects

Nanostructures

Self interstitial clusters

Tool wear detection and self-induced vibrations control in turning operations

Orozco Mendoza, Horacio

10 June 2011

Not available / text

Process control--Automation

Self-induced vibration

Strain gages

An investigation into the failure of aluminum alloys

Hickey, William Fassett

03 October 2011

The rate dependence of several aluminum alloys (6061, 7075, 5083) was examined through the means of quasi-static tension tests, dynamic tension tests, and split pressure Hopkinson bar tests. The macroscopic strains of the quasi-static and dynamic tension tests were measured after failure within the uniform region and the necked region using high-resolution images and edge detection. The study continued with an exploration into the plane-stress ductile fracture of Al 6061 in the T6 and O condition. Digital image correlation (DIC) was used to find the displacement and strain fields, and a numerical method for calculating the stress fields for a power law hardening material was developed. The J-integral was then calculated locally. The effect of strain hardening on the type of fracture (slant or flat) was also investigated. Macroscopic and microscopic observations of the fracture were made with DIC and by dissecting, polishing and/or etching the broken fracture specimens. Local failure strain measurements were made on the grain level and compared with those found through traditional failure strain measurements. / text

J-integral

Digitil image correlation

Grain level strain