Tvorba elektronických učebních materiálů pro výuku fyziky na ZŠ / Creation of electronic material for physics education

BARABÁŠ, Vít

January 2015

The presented diploma thesis deals with designing electronic educational materials intended for learning/teaching physics at elementary schools. The work consists of the following parts. In the first part, we focuse on the description of the used HTML5 technology and its possibilities.Subsequently we analyze the applicability of the chosen technologies. The main part of the work comprises a description of designing and implementation of five selected teaching methods and their testing on interactive whiteboards and contemporary mobile devices.

Effect of Cell-Substrate Interactions on Epithelial Cell Mechanics

Gullekson, Corinne

24 September 2018

Cell-substrate interactions play a key role in the regulation of epithelial cell mechanics. Through a series of studies, we demonstrate how substrate interactions impact both the response to an oncogene and the cellular contractility and organization of a monolayer. We first examine the effects of oncogenic Ras in cells in adherent and suspended states. To accomplish this, we utilized atomic force microscopy and a microfluidic optical stretcher. We found that adherent cells stiffen and suspended cells soften with the expression of constitutively active Ras. The effect on adherent cells was reversed when contractility was inhibited with the ROCK inhibitor Y-27632, resulting in softer cells. These findings suggest that increased ROCK activity as a result of Ras has opposite effects on suspended and adhered cells. In a subsequent study, we examined the effects of a substrate on contracting and relaxing monolayers. We created a new methodology for measuring the mechanodynamics of epithelial monolayers by culturing cells at an air-liquid interface. These model monolayers were grown in the absence of any supporting structures in hanging drops. We found that the direction of strain in the unsupported monolayers was not correlated to nuclear alignment as observed when the monolayers were grown on soft deformable gels. It was also observed that both gel and glass substrates led to the promotion of long-range cell nuclei alignment not seen in the unsupported monolayers. To further characterize the morphology and mechanics of monolayers clusters observed in our experiments, we created a new computational model based on the vertex model. The energy function used in this model takes into account cell-cell and cell-substrate adhesion as well as anisotropic cellular mechanical properties. The results of these simulations suggest that the promotion of long-range alignment on solid substrates were due to cells having anisotropic elastic moduli with global alignment. They also suggest that the alignment observed in monolayers grown on air water interfaces is due to cells having low substrate adhesion and isotropic moduli. Our findings establish the importance of studying epithelial cell mechanics in different states of attachment.

cell mechanics

optical stretcher

hanging drop

substrate

ras

An investigation into the possible causes of the difference between the boys' and girls' drop-out rate in mathematics at the end of the junior secondary phase of education

Oberholster, E J

January 1986

In the past two decades much research in the field of Mathematics in Education has dealt with boy- girl differences. In the 1960's sex differences in mathematical achievement played an important role in research. The results of more recent and better controlled studies seem to indicate that overall boy-girl differences in mathematical achievement are probably negligible at the Primary stage and exist at the Secondary stage principally in areas involving spatial visualization and problem solving.

Mathematical ability

Gender

Mathematics teaching

Drop-out rate

Junior secondary

The Effect of Gluteus Medius Muscle Activation on Lower Limb Three-dimensional Kinematics And Kinetics in Male and Female Athletes during Three Drop Jump Heights

Nowak, Stephanie Christine

January 2012

Women are four to eight times more likely to injure their anterior cruciate ligament (ACL) compared to men. It is most commonly injured through a non-contact mechanism during game time situations. During landings, women display valgus collapse, where a less active gluteus medius muscle (GMed) may be unable to control the internal rotation of the thigh, causing an increase in knee joint abduction angle, augmenting the risk of ACL injury. This study’s purpose was to determine the difference between 12 male and 12 female athletes in muscle activity, specifically the GMed, and the 3D kinematics and kinetics of the lower-limb during drop jump landings from three heights; maximum vertical jump height, tibial length, and a commonly used height of 40cm. Results showed that females had greater hip adduction and knee abduction angles compared to men. The GMed activity showed no significant differences between sexes at each drop jump height.

gluteus medius

ACL injury

intramuscular electrodes

drop jumps

sex differences

Two-Phase Interactions on Superhydrophobic Surfaces

Stevens, Kimberly Ann

01 December 2018

Superhydrophobic surfaces have gained attention as a potential mechanism for increasing condensation heat transfer rates. Various aspects related to condensation heat transfer are explored. Adiabatic, air-water mixtures are used to explore the influence of hydrophobicity on two-phase flows and the hydrodynamics which might be present in flow condensation environments. Pressure drop measurements in a rectangular channel with one superhydrophobic wall (cross-section approximately 0.37 X 10 mm) are obtained, revealing a reduction in the pressure drop for two-phase flow compared to a control scenario. The observed reduction is approximately 10% greater than the reduction that is observed for single-phase flow (relative to a classical channel). Carbon nanotubes have been used to create superhydrophobic coatings due to their ability to offer a relatively uniform nanostructure. However, as-grown carbon nanotubes often require the addition of a thin-film hydrophobic coating to render them superhydrophobic, and fine control of the overall nanostructure is difficult. This work demonstrates the utility of using carbon infiltration to layer amorphous carbon on multi-walled nanotubes to achieve superhydrophobic behavior with tunable geometry. The native surface can be rendered superhydrophobic with a vacuum pyrolysis treatment, with contact angles as high as 160 degrees and contact angle hysteresis less than 2-3 degrees. Drop-size distribution is an important aspect of heat transfer modeling that is difficult to measure for small drop sizes. The present work uses a numerical simulation of condensation to explore the influence of nucleation site distribution approach, nucleation site density, contact angle, maximum drop size, heat transfer modeling to individual drops, and minimum jumping size on the distribution function and overall heat transfer rate. The simulation incorporates the possibility of coalescence-induced jumping over a range of sizes. Results of the simulation are compared with previous theoretical models and the impact of the assumptions used in those models is explored. Results from the simulation suggest that when the contact angle is large, as on superhydrophobic surfaces, the heat transfer may not be as sensitive to the maximum drop-size as previously supposed. Furthermore, previous drop-size distribution models may under-predict the heat transfer rate at high contact angles. Condensate drop behavior (jumping, non-jumping, and flooding) and size distribution are shown to be dependent on the degree of subcooling and nanostructure size. Drop-size distributions for surfaces experiencing coalescence-induced jumping are obtained experimentally. Understanding the drop-size distribution in the departure region is important since drops in this size are expected to contribute significantly to the overall heat transfer rate.

superhydrophobic surfaces

condensation

two-phase flow

drop-size distribution

Engineering

Boiler feed pump low load – leak off recirculation study

van Tonder, Daniël

26 November 2021

For power plants that make use of high energy boiler feed pumps, there is a risk that the boiler feed pump may experience cavitation and overheating at low load and start-up conditions. These plants make use of a leak off or recirculation system that diverts some of the flow back to the feed water tank, ensuring that a minimum flow through the pump is maintained at low load and start-up operating conditions. The recirculation valve, also known as a leak off valve, experiences a very high pressure difference and cavitation pitting is common due to the water being close to saturation. There are various ways in which the recirculation flow is controlled in the industry such as open orifice, on/off binary type control valves, automatic recirculation valves (ARC) or modern modulating leak off systems. The valves themselves can also be simple plug type or make use of pressure staging to reduce the risk of cavitation. This project involves modelling the flow system around the boiler feed pump and its control for the various architectures employed in Eskom. This is to assist in understanding the reasons for cavitation damage that is found in some recirculation valves as well as the low load capability of the system. Single stage components with extremely high pressure drops are singled out as components with the highest risk of cavitation in the systems. Although extremely high pressure drops are found across the leak off valves themselves, the majority of the valves are multistage valves which are specifically designed to accommodate cavitation development and are therefore not of major concern. Some of the findings of the study are: The rule of thumb used within Eskom to determine the amount of pressure reducing stages on leak off valves could be more conservative. The specification of new valves and components for the leak off systems requires accurate specification based on detailed process models, such as the ones developed for this study. The full range of all possible operational cases must also be considered during the design.

Boiler Feed Pump

Leak Off

Cavitation

Pressure Drop

Critical Valve

Job Satisfaction, Organizational Commitment, and Turnover Intention of Teachers Using Computer-Based Curriculum Delivery in a Drop-Out Recovery High School

Beauchamp, Joey

12 1900

This current study examined the job satisfaction and turnover intention of teachers working in a drop out recovery program using online curriculum. The subjects of the study were from one charter school district in north Texas that is designated as a drop out recovery program. This qualitative case study used interviews and focus groups to examine eight different areas of teacher job satisfaction to examine factors that influence a teacher's intent to quit or remain at a school. Previous research showed a connection between job satisfaction levels and the intent of a teacher to terminate employment or not. Previous research had not looked into this specific school environment. Results showed that compensation was the largest factor in job satisfaction but negative feelings could be overcome if other areas of importance for teachers brought positive job satisfaction. Overall, teachers in this environment were more likely to have high job satisfaction and less likely to terminate employment.

Job Satisfaction

Turnover Intention

Drop out recovery

online curriculum

Relationship Between Lower Body Strength, Countermovement Jump Height, and Optimal Drop Jump Drop Height

Griggs, Cameron V

01 August 2016

The purpose of this study was to understand the relationship between back squat one-repetition maximum relative to body mass (1RMrel), countermovement jump height (CMJH), and optimal drop height in drop jump (DHopt). Fifteen male participants with various sport backgrounds and training experience completed a one repetition maximum (1RM) back squat, maximum countermovement jump (CMJ), and drop jumps (DJ) from incrementally increasing drop heights to determine which drop height elicited the greatest jump height. The DHopt testing protocol was unique in that smaller increments were used to determine DHopt compared to what has been reported in literature previously. Pearson correlation coefficients revealed that DHopt had small (r=0.214) and moderate (r=0.464) relationships with 1RMrel and CMJH, respectively. A second analysis (n=13) was conducted after two participants (i.e. powerlifters) were identified as possibly being representative of a different population. The second analysis found that DHopt had strong relationships with 1RMrel (r=0.645) and CMJH (r=0.690). Results from this study seem to suggest that individuals with greater 1RMrel and CMJH tend to have a higher DHopt. However, this relationship may not be observed among all populations due to likely differences in sport background, genetics, and/or training experience.

back squat

countermovement jump

drop jump

jump height

Exercise Science

Automatizované optické měření kontaktního úhlu kapky / Automated optical measurement of drops contact angle

Dugáček, Ján

January 2018

Measurement of surface tension of solids usually requires manual processing of photographs of droplets of liquids with known properties on the measured material's surface, during which the contact angle is manually determined. The objective of this work is to implement an algorithm that can determine these contact angles from photographs and does not require the photographs to be made under specific light conditions. The implementation cannot depend on paid libraries and must be simple to incorporate into existing software.

Drop Impacts Under Extreme Conditions on Thin Liquid Films or Solid Walls

Aljedaani, Abdulrahman Barakat

10 1900

Drop impacts play a key role in many industrial applications, from spray coating of surfaces, to splashing of fuel-droplets within combustion chambers. Splashing, or break-up during ink-jet printing, can cross-contaminate biological assays, or degrade the quality of ink-jet printed products. Crime scene studies of blood splatter can give vital clues for the police. Spreading of plant diseases between nearby leaves by splashing depends on the velocity and trajectory of secondary droplets. In this dissertation, I study the early dynamics of splashing and the dynamics of ejecta sheets under extreme impact conditions, using ultra-high-speed video imaging at up to 5 million fps. In the first part, I show the effect of the surface tension differences on the break-up of the Edgerton crown, I verify that individual droplets hit the crown wall and generated Marangoni holes, thereby causing the crown wall to rupture at multiple locations. In the second part, I investigate the splashing of a drop impacting onto a solid substrate with high impact velocity, I show that for sufficiently high Re, splashing can no longer be suppressed by only reducing the surrounding air pressure. Furthermore, I tracked the earliest splashed spray droplets to catch their maximum velocity. Surprisingly, the splashed droplets can travel at extremely high speed of up to 1 km/s, which is 50 times faster than the impact speed. The influence of viscosity on the lamellar spreading along the substrate was investigated. I find that the intact lamella, following the fine spray, spreads as R(t) ~〖 t〗^(1/3) , while the maximum spreading radius of the drop was shown to be a strong function of viscosity, scaling as β_max∝〖Re〗^0.175. The data did not show a strong effect of surface tension on β_max over a wide range. Therefore, I concluded that surface tension at this parameter space does not play a major role in both splashing nor spreading. In the third part, I study extreme splashing dynamics of the Ejecta sheet when a drop impacts on a thin liquid film with very large impact velocities using the same device, at up to ~ 22 m/s. For this purpose, we have constructed a novel experimental device consisting of a 26-m-tall vacuum tube. I investigate the interplay between viscosity, the surrounding ambient air pressure, and surface tension, on the ejecta shapes and break-up. I show how the bending of the ejecta sheet is primarily produced by air-resistance. This is supported by an analytical and numerical model to quantify the effect of the surrounding air pressure on the sheet bending and touch-down.

splashing

Drop impact

Marangoni

Capillary flow

Ejecta sheet