The Relationship Between Task-Induced Stress and Time Perception

Brosnihan, Annamarie

01 January 2023

A distortion of time is often reported under the presence of stress or threatening stimuli, for instance motor vehicle accidents or near-death experiences. There is a lack of research on the complexity of time distortion under stress; thus, the present study aimed to explore the relationship between stress and time perception. Given the challenges associated with producing a stress response in a laboratory setting, difficult tasks have been previously used to produce a stress response, such as anagram tasks. However, it remains unknown whether experiencing time pressure while completing a stressful task can also influence time distortion. To investigate this, participants completed either an easy or difficult anagram task and received either an unspecified time limit or no time limit to complete the task. It was hypothesized that participants would experience the greatest distortion of time when the task was difficult, and they were provided an unspecified time limit. Contrary to the hypothesis, we failed to find differences in task performance or time perception across the various conditions, which may be explained by the inability to produce a stress state. While stress manipulation was unsuccessful, the findings suggest utilizing multiple tasks may be more effective at replicating a physiological or psychological stress state. Thus, the results of this study warrant further investigation to examine the relationship between stress, time pressure, and time distortion.

task-induced stress

time perception

time distortion

Psychology

Involvement of abscisic acid and H2O2 in antioxidant enzyme activities mediated by nitric oxide synthase-like activity in maize

Hlatshwayo, Siphiwe Gift

January 2018

>Magister Scientiae - MSc / In recent years, nitric oxide (NO) has emerged as an important endogenous plant signalling molecule that mediates many developmental and physiological processes. NO regulates the activity of antioxidant enzymes in response to droughtinduced stress by controlling the expression of the genes that encode these enzymes. Antioxidant enzymes function in scavenging reactive oxygen species like superoxide ion (O2 -) and hydrogen peroxide (H2O2) that are generated in response to drought-induced stress and other abiotic stresses. Abscisic acid, a phytohormone that acts as a stress-related hormone in plants, also stimulates production of H2O2, thus further triggering the antioxidant enzyme activity in order to scavenge the excess H2O2. Accumulated data indicate that NO interacts with reactive oxygen species, notably hydrogen peroxide and superoxide. This study was aimed at clarifying the role of NO derived from nitric oxide synthase-like (NOS-like) enzymatic activity in scavenging of H2O2 and to establish if this is dependent or independent of ABA signaling. This was achieved by using Nω-Nitro-L-Arginine methyl ester (L-NAME), an inhibitor of NOS to control the amount of NO in maize tissue. The study investigated the effect of L-NAME on the accumulation of superoxide, which is scavenged by superoxide dismutase. Furthermore, the study determined the role of NOS-like activity in ABA-mediated production of H2O2. Lastly, the effect of L-NAME on H2O2 accumulation and antioxidant enzyme activity was also investigated. Application of L-NAME altered the enzymatic activity of superoxide dismutase, ascorbate peroxidase and catalase. These changes in enzymatic activity were coupled with altered levels of O2 - and H2O2 in leaves and roots. Treatments with ABA in combination with L-NAME resulted in reversal of H2O2 content to basal levels. These results suggest that nitric oxide, produced by nitric oxide synthase-like activity, is important in regulation of antioxidant enzyme activity and cross-talks with ABA.

Drought-induced stress

Abscisic acid

Hydrogen peroxide

Zea mays

Reactive oxygen species

Nitric oxide

Ultrafast Laser Induced Thermo-Elasto-Visco-Plastodynamics in Single Crystalline Silicon

Qi, Xuele

2009 December 1900

A comprehensive model for describing the fundamental mechanism dictating the interaction of ultrafast laser pulse with single crystalline silicon wafer is formulated. The need for establishing the feasibility of employing lasers of subpicosecond pulse width in Laser Induced Stress Waves Thermometry (LISWT) for single crystalline silicon processing motivated the work. The model formulation developed is of a hyperbolic type capable of characterizing non-thermal melting and thermo-elastoviscoplastic deformation as functions of laser input parameters and ambient temperature. A plastic constitutive law is followed to describe the complex elasto-viscoplastic responses in silicon undergoing Rapid Thermal Processing (RTP) annealing at elevated temperatures. A system of nine first-order hyperbolic equations applicable to describing 3-D elasto-viscoplastic wave motions in silicon is developed. The group velocities of certain selected frequency components are shown to be viable thermal indicators, thus establishing the feasibility of exploiting nanosecond laser induced propagating stress waves for the high-resolution thermal profiling of silicon wafers. Femtosecond laser induced transport dynamics in silicon is formulated based on the relaxation-time approximation of the Boltzmann equation. Temperature-dependent multi-phonons, free-carrier absorptions, and the recombination and impact ionization processes governing the laser model and carrier numbers are considered using a set of balance equations. The balance equation of lattice energy and equations of motion of both parabolic and hyperbolic types are derived to describe the complex thermo-elastoplastodynamic behaviors of the material in response to ultrafast laser pulsing. The solution strategy implemented includes a multi-time scale axisymmetric model of finite geometry and a staggered-grid finite difference scheme that allows both velocity and stress be simultaneously determined without having to solve for displacements. Transport phenomena initiated by femtosecond pulses including the spatial and temporal evolutions of electron and lattice temperatures, along with electron-hole carrier density, are found to be functions of laser fluence and pulse width. The femtosecond laser heating model that admits hyperbolic energy transport is shown to remedy the dilemma that thermal disturbances propagate with infinite speed. Non-thermal melting fluence is examined favorably against published experimental data. That it is feasible to explore femtosecond laser induced displacement and stress components for 1K resolution thermal profiling is one of the conclusions reached.

Single Crysalline Silicon

Ultrafast Laser

Thermo-elasto-visco-plastodynamics

Laser Induced Stress Waves Thermometry

Acoustically Induced Stress Analysis Of Center Fuselage Skin Panels Of A Basic Training Aircraft Using Statistical Energy Analysis

Kurtoglu, Ilker

01 June 2009

Two sample statistical energy analysis (SEA) models are generated for a section of the fuselage panel of an aircraft, namely the uniform panel model which includes the frames and stringers, and the ribbed panel model in which the frames and stringers are smeared into the skin. Turbulent boundary layer (TBL) excitation is used as the primary acoustic excitation source. Stress levels are estimated from the average velocity data of the panels. The stress results are found comply with those obtained by the AGARD method. Effect of radiation from panels to exterior and interior of the sample skin panel as well as the pressurization of the skin panels are investigated separately to analyze their effects on the stress levels. The method is then used in the analysis of center fuselage skin panels on a basic training aircraft. Two models are generated for the aircraft analysis, namely the complete aircraft model and the simplified model which excludes the wings and the empennage. In addition to TBL, propeller noise is used as the primary acoustic excitation source. The effects of the wings and the empennage on the stress levels in the center fuselage skin panels are also investigated along with the radiation from panels to the exterior and interior of the aircraft and pressurization of the pilot cabin.

QC Acoustics, Sound 221-246

Can stress-related behavior in dogs be due to pain? A pilot study.

Pettersson, Alice

January 2015

Dogs and other pets can have back pain for years that no one notices. As a result they become stressed and can e.g. develop aggressiveness or decrease their feeding. There are indications that chiropractic treatments can treat these animals but this is not commonly known by veterinarians. This study investigated stress related behaviors and average heart rate in ten dogs before and after chiropractic treatment. A control group of eight dogs was also tested but did not receive the treatment. The test consisted of three parts: 1) one part without owner interaction, 2) one part where a human approached and 3) one part were the owner commanded the dog to sit and lie down. Eight out of ten owners experienced a positive change in their dogs’ behavior one week after the treatment though the test results did rather point at more stressful behaviors. The test group showed an increase in yawning and panting from the first to the second test (after the treatment) and showed a higher heart rate after the treatment compared to the control group during part 1. Probably due to that the treatment and the tests were in the same local and the dogs became stressed by being there again. Part 3 did show a possible increase in movability and contact with the owner but more studies are needed to confirm the change that the owners experienced. Though, this study is a step in the right direction; more animals could be treated and saved from euthanizing if chiropractic and the diagnosis of this back injury are taught to veterinarians.

Dogs

canine behavior

stress-related behavior

stress

pain

pain-induced stress

chiropractic

Investigation of Chloride-induced Stress Corrosion Cracking for Long-Term Storage of Spent Nuclear Fuel in Dry Storage Systems

Shakhatreh, Abdulsalam Ismail

14 September 2022

Chloride-induced stress corrosion cracking (CISCC) has been identified as the main degradation mechanism for spent nuclear fuel dry storage canisters. This type of induced cracking is complex and depends on several factors, such as material composition, exposure temperature, relative humidity, applied tensile stress, and atmospheric salt concentration. An accelerated experiment was designed to simulate marine environments in a controlled fogging chamber to examine 304 and 304L stainless steel U-bend and welded U-bend samples. The samples were exposed to chloride rich and humid fogging in a corrosion chamber at 35℃ continuously for 4 weeks, 8 weeks, and 12 weeks. The same experiment was repeated at 50℃ for 4 weeks, 8 weeks, and 14 weeks to study the sensitivity of CISCC to temperature changes. A qualitative evaluation of optical micrographs from a 3D Surface Profiler was performed for 16 corroded samples and compared with 2 reference samples. Cracking was observed on 12 out of 16 samples exposed to 35℃ and 50℃ for durations ranging from 8 to 14 weeks. Likely cracking observations were noted on 4 out of 16 samples. A quantitative statistical analysis was also performed using surface profile depth (valley) data from corroded and reference samples. The quantitative analysis examined the effect of temperature, welding, exposure duration, and material composition. The quantitative results were compared with the qualitative results and literature published in CISCC. / Master of Science / Most nuclear power plants are currently using dry storage canisters (DSCs) which are made of a concrete vault and a stainless steel canister that houses the spent nuclear fuel (SNF) assemblies. Multiple conditions must be present simultaneously for chloride-induced stress corrosion cracking (CISCC) to develop, such as the presence of a susceptible alloy, high relative humidity, high temperature, high atmospheric salt concentrations, and applied tensile stresses. DSCs are typically made from 300-series austenitic stainless steels which are susceptible to this type of corrosion during long-term storage near marine environments. Therefore, understanding of the factors leading to CISCC is critically important for proper management and mitigation and to estimate the service life of DSCs for the safe long-term storage of SNF. An accelerated experiment was designed to examine the effects of temperature, exposure duration, and welding on pitting and cracking for 304 and 304L U-bend samples. The experimental results concluded that stainless-steel grades 304 and 304L are susceptible to CISCC when exposed for 8 weeks or longer to fogging at temperatures between 35℃ and 50℃, 95% relative humidity, and 5% salt concentration. This study also concluded that increasing exposure duration from 8 to 12 weeks or the temperature from 35℃ to 50℃ had no significant effect on the acceleration of CISCC. Also, unwelded samples were deemed more susceptible to CISCC than welded samples and the susceptibility of 304 and 304L grades were relatively similar.

stress corrosion cracking

spent nuclear fuel dry storage

CISCC

SCC

ISFSI

Preference for Alcohol as a Coping Mechanism in a Task-Induced Stress Situation

Trich Kremer, Jennifer D.

06 August 2010

No description available.

Personality

coping

task-induced stress

personality

alcohol expectancies

alcohol consumption

vigilance task

Chloride-Induced Stress Corrosion Cracking in Used Nuclear Fuel Welded Stainless Steel Canisters

Xie, Yi

28 December 2016

No description available.

Nuclear Engineering

Low-temperature pausing : an alternative short-term preservation method for use in cell therapies

Robinson, Nathalie J.

January 2016

With encouraging advancements in cell therapies, there is a requirement for an effective short-term cell preservation method, enabling time for quality assurance testing and transport to their clinical destination. This project aims to pause cells at ambient temperatures, whilst maintaining viability and function post-preservation. Ambient cell preservation bypasses ice crystal exposure and toxic solute concentrations experienced with cryogenic storage. Storage in ambient conditions also avoids use of toxic cryoprotectants and aims to greatly reduce costs and reliability on specialist machinery. Early work used HOS TE85 cells (derived from an osteosarcoma) as a model. When atmospheric factors were controlled, HOS TE85 cells demonstrated effective recovery in terms of morphology, membrane integrity (viability >90%) and fold growth expansion when paused at ambient temperature for up to 144 hours. Without atmospheric control, addition of the buffering agent HEPES (25mM) to cell medium was required to keep viability above 70%, as well as to maintain yield and continual passage following 144 hours pausing. The pausing potential of therapeutically relevant human mesenchymal stem cells (hMSCs) from three individual donors (M2, M3 and M4) was tested by keeping cells in suspension for up to 72 hours. Using standard medium with the addition of 25mM HEPES, average membrane integrity was maintained above 70%. Following pausing for between 24 72 hours, hMSC attachment efficiency, immunophenotype and tri-lineage differentiation capacity (osteogenesis, adipogenesis and chondrogenesis) remained similar to non-paused cells. Apart from a short lag phase on the first passage, hMSC fold growth expansion level was consistent with the control for all three donors over 3 x 6 day passages. The colony forming unit (CFU) efficiency of paused cells was significantly reduced when compared with non-paused M2 and M4 lines, whilst M3 retained a similar CFU efficiency to its non-paused counterpart. On return to normal culture conditions, hMSCs had comparable metabolic activity rates with non-paused cells for up to 9 hours. Stable pH is vital during pausing and additional antioxidants or apoptotic inhibiters may be required to keep average viability well-above the 70% threshold, set by the US Food and Drug Administration. Collectively, results have been encouraging and show potential for the movement towards using ambient temperature preservation as an option for the short-term storage and transport of cells for therapy.

616.02

A Study of Moisture Induced Material Loss of Hot Mix Asphalt (HMA)

Arepalli, Uma Maheswar

04 December 2017

"Susceptibility of Hot Mix Asphalt (HMA) mixes to moisture induced damage is one of the main reasons for premature failures of asphalt pavements. Hence, the evaluation of mixes for the moisture susceptibility is an essential part of the mix design. The existing methods are found to be in-sufficient to characterize mixes in terms of their moisture damage potential, and many studies have been conducted to establish an improved methodology that can better address the issue. Most of these methods involve the determination of changes in mix properties due to moisture conditioning in the laboratory or to verify the mix performance in the field or the laboratory. In the field moisture susceptible mixes are also found to lose material to extents that are dependent upon the properties of the mix and materials. So far, there has been no comprehensive study to investigate the loss of materials due to moisture induced damage. The objective of this study was to identify and evaluate a conditioning and a test method that can be used on a regular basis to detect moisture susceptible mixes and to understand the combined problem of moisture induced material loss and change in strength/stiffness of the mix. The Moisture Induced Stress Tester (MIST), Ultrasonic Pulse Velocity (UPV), Dynamic Modulus in Indirect tensile mode, and Indirect Tensile Strength (ITS) tests were utilized in the study. The effluent from the MIST was checked for the gradation of dislodged aggregates and the Dissolved Organic Carbon (DOC) content. A system dynamics (SD) approach was also adopted to investigate the problem and establish a model to reproduce field observations. The results showed that the use of MIST in combination with UPV or ITS is able to identify moisture susceptible mixes, in particular for mixes with the potential of aggregate breakdown. The mixes with a higher loss of asphalt binder during conditioning exhibit higher tensile strengths, and those with a loss of finer materials, which is indicative of aggregate breakdown, show a lower tensile strength. For the mixes used in this study, the rate of change in indirect tensile strength during moisture conditioning was found to be strongly correlated to the pre-conditioning modulus of the mix. A step-by-step framework to characterize the moisture susceptible mixes was presented."

moisture damage

Moisture Induced Stress Tester

dynamic modulus

fineness modulus

dissolved organic carbon

system dynamics

indirect tensile strength

seismic modulus

asphalt

HMA