Parallel adaptive finite element methods for problems in natural convection

Peterson, John William,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2008. / Vita. Includes bibliographical references.

Thermocapillary micromanipulation: laser-induced convective flows towards controlled handling of particles at the free surface

Terrazas Mallea, Ronald

12 December 2017

EN: There is an industrial need for new technologies that can manipulate objects in the micrometric scale (1-1000 μm). In this thesis, an original non-contact actuation technique for the manipulation of microscale objects is proposed. The proposal is to use laser-induced thermocapillary convective flows to manipulate particles at the fluid/gas interface. These flows are generated when a surface tension stress is generated at the fluid/gas interface due to a thermal gradient. Laser heating is used because the generated thermal gradients produce fast, localized flows that improve the actuation performance. The particles are manipulated at the interface because the flow generated there is the fastest in the entire fluid. To ensure the precise positioning of a particle, closed-loop controllers are implemented in the system which are designed based on models proposed for the system. Experimental tests are performed that show that positioning precision can be ensured. In addition, the interaction forces between particles have been studied which is a preliminary step towards parallel manipulation. To counteract those forces during the manipulation, a different control strategy has been proposed, implemented and tested using simulations. Overall, the results obtained are comparable to the ones obtained with the other techniques. Therefore, the proposed technique can be considered as an attractive alternative that offers different advantages and disadvantages. FR: Il existe un besoin industriel croissant de nouvelles technologies capables de manipuler des objets à l’échelle micrométrique (1-1000 μm). Dans cette thèse, une technique originale d’actionnement sans contact pour la manipulation d’objets à l’échelle micrométrique est proposée. Elle est basée sur les écoulements thermocapillaires convectifs induits par un laser pour manipuler des particules à l’interface fluide/gaz. Le laser chauffe localement la surface de l’eau, ce qui induit un gradient de tension de surface. Ce gradient génère un écoulement fluidique. Ces écoulements sont rapides et localisés, ce qui confère des performances intéressantes à cette technique d’actionnement. Les particules sont manipulées à l’interface fluide/gaz, où l’écoulement généré est le plus rapide.Pour assurer le positionnement précis d’une particule, des contrôleurs en boucle fermée sont implémentés dans le système. Ils sont basés sur les modèles développés dans cette thèse. Des essais expérimentaux montrent que le positionnement précis de particules peut être assuré. De plus, les forces d’interaction entre des particules placées à l’interface ont été étudiées, et une stratégie de contrôle a été proposée, en vue de la manipulation en parallèle de plusieurs particules. Tant les études analytiques et les simulations numériques que les tests expérimentaux soulignent l’intérêt des écoulements thermocapillaires convectifs pour la manipulation contrôlée d’objets micrométriques. Cette technique est donc une alternative prometteuse aux approches classiques d’actionnement sans contact. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Micromanipulation

Control

Surface tension

Microfluidics

The relationship of interfacial energy to graphite shape in the Fe-C system.

Hawbolt, Edward Bruce

January 1964

The relationship between surface energy and precipitated graphite form in Fe-C alloys was examined in this thesis.Surface tension and contact angle data were obtained using the sessile drop technique. Carbon saturated, puron iron crucibles were melted on pyrolytic graphite, the effect of time, temperature (1500-1600°C) and additions of Ni, Mn, S or Ce being examined. The graphite form was established by metallographic examination. An average ƔLV of 1152 dynes/cm was determined for the Fe-C alloys (4.6% C) at approximately 1300°C, the average contact angle being 128°. No significant change occurred with additions of Ni ( 0.85%) and Mn ( 1.65%). Additions of S lowered the surface energy and increased the equilibrium contact angle. Ce additions had a similar effect although a direct comparison with the Fe-C alloys could not be made as different temperatures were used. However, the interfacial energy difference apparently increased with increasing Ce content, implying an adsorption of Ce to the graphite-melt interface. The change from the flake to the nodular form was accomplished in several transition stages, the interfacial energy differences being small, indicating a marked dependence on the solidification and growth conditions. / Applied Science, Faculty of / Materials Engineering, Department of / Graduate

Graphite

Carbon

Iron-carbon alloys

Surface tension

A Volume of Fluid (VoF) based all-mach HLLC Solver for Multi-Phase Compressible Flow with Surface-Tension

Oomar, Muhammad Yusufali

15 September 2021

This work presents an all-Mach method for two-phase inviscid flow in the presence of surface tension. A modified version of the Hartens, Lax, Leer and Contact (HLLC) approximate Riemann solver based on Garrick et al. [1] is developed and combined with the popular Volume of Fluid (VoF) method: Compressive Interface Capturing Scheme for Arbitrary Meshes (CICSAM). This novel combination yields a scheme with both HLLC shock capturing as well as accurate liquid-gas interface tracking characteristics. To ensure compatibility with VoF, the Monotone Upstream-centred Scheme for Conservation Laws (MUSCL) [2] is applied to non-conservative (primitive) variables, which yields both robustness and accuracy. Liquid-gas interface curvature is computed via both height functions [3, 4] and the convolution method [5]. This is in the interest of applicability to both cartesian and arbitrary meshes. The author emphasizes the use of VoF in the interest of surface tension modelling accuracy. The method is validated using a range of test-cases available in literature. The results show flow features that are in agreement with experimental and benchmark data. In particular, the use of the HLLC-VoF combination leads to a sharp volume fraction and energy field with improved accuracy (up to secondorder).

VoF

Compressible

Surface Tension

CSF

Height Functions

Investigations of Surface-Tension Effects Due to Small-Scale Complex Boundaries

Feng, Jiansheng

01 February 2013

The earliest man-made irrigation systems in recorded history date back to the ancient Egypt and Mesopotamia era. After thousands of years of experience, exploration, and experimenting, mankind have learned how to construct canals and dams and use pipes and pumps to direct and control water flow, but till this day, there are still some behaviors of water and other simple fluids that surprise us. One such example is the lotus effect: a surface-tension effect which allows raindrops to roll freely on a lotus leaf as if they were drops of mercury. One of the key factors that determine how a fluid system behave is the size-scale. Fluids flow at small scales very differently than they do at large scales. The standard comparing to which small and large are defined is the capillary length. A number of surface-tension related phenomena are unfamiliar because they are only noticeable at length-scales of a few millimeters or below, and they look nothing like what we would expect fluids to behave when dominated by gravity. As fascinating as many of them may seem at first glance, surface-tension phenomena are actually not that far away from our daily lives. Surface tension is everywhere because it costs energy to create areas of surfaces and interfaces, just like it costs energy to deform a solid (resulting in elasticity) or to elevate a weight (resulting in gravity). To minimize energy, a surface or an interface has the tendency to contract, and this tendency generates surface tension. The size of a system significantly affects the relative strengths of surface-tension effects comparing to effects of body forces, most commonly gravity. By equating the estimated magnitudes of surface tension and gravitational forces of a system, a length scale, know as the capillary length, can be defined. The capillary length of water on earth is about 2.7 mm. At the length scale of everyday objects, which is usually above the capillary length, surface-tension effects are not always prominent, because at those scales the competing force, gravity, is often much stronger. That is why the surface of a glass of water is more or less flat. However, as the size-scale decreases, surface tension decreases a lot slower than gravity, so when the size of a fluid system gets down to below the capillary length, surface tension takes over. One of the defining characteristics of this moment in human history, is the tremendous efforts we are putting into the research and engineering of micro- and nano-scale materials and structures − systems where surface tension is often the predominant force. It is important to study surface-tension effects so that we can use them to our advantage. In this Ph.D. dissertation, we have investigated some important surface-tension phenomena including capillarity, wetting, and wicking. We mainly focus on the geometric aspects of these problems, and to learn about how structures affect properties. Understanding these phenomena can help develop fabrication methods (Chapter 2), study surface properties (Chapter 3), and design useful devices (Chapter 4) at scales below the capillary length. In the first project (Chapter 2), we used numerical simulations and experiments to study the meniscus of a fluid confined in capillaries with complicated cross-sectional geometries. In the simulations, we computed the three-dimensional shapes of the menisci formed in polygonal and star-shaped capillaries with sharp or rounded corners. Height variations across the menisci were used to quantify the effect of surface tension. Analytical solutions were derived for all the cases where the cross-sectional geometry was a regular polygon or a regular star-shape. Power indices that characterize the effects of corner rounding were extracted from simulation results. These findings can serve as guide for fabrications of unconventional three-dimensional structures in Capillary Force Lithography experiments [J. Feng (2011) (a)]. Experimental demonstrations of the working principle was also performed. Although quantitative matching between simulation and experimental results was not achieved due to the limitation of material properties, clear qualitative trends were observed and interesting three-dimensional nano-structures were produced. A second project (Chapter 3) focused on developing techniques to produce three-dimensional hierarchically structured superhydrophobic surfaces with high aspect ratios. We experimented with two different high-throughput electron-beam-lithography processes featuring single and dual electron-beam exposures. After a surface modification procedure with a hydrophobic silane, the structured surfaces exhibited two distinct superhydrophobic behaviors − high and low adhesion. While both types of superhydrophobic surfaces exhibited very high (approximately 160_) water advancing contact angles, the water receding contact angles on these two different types of surfaces differed by about 50_ _ 60_, with the low-adhesion surfaces at about 120_ _ 130_ and the high-adhesion surfaces at about 70_ _ 80_. Characterizations of both the microscopic structures and macroscopic wetting properties of these product surfaces allowed us to pinpoint the structural features responsible for specific wetting properties. It is found that the advancing contact angle was mainly determined by the primary structures while the receding contact angle is largely affected by the side-wall slope of the secondary features. This study established a platform for further exploration of the structure aspects of surface wettability [J. Feng (2011) (b)]. In the third and final project (Chapter 4), we demonstrated a new type of microfluidic channel that enable asymmetric wicking of wetting fluids based on structure-induced direction-dependent surface-tension effect. By decorating the side-walls of open microfluidic channels with tilted fins, we were able to experimentally demonstrate preferential wicking behaviors of various IPA-water mixtures with a range of contact angles in these channels. A simplified 2D model was established to explain the wicking asymmetry, and a complete 3D model was developed to provide more accurate quantitative predictions. The design principles developed in this study provide an additional scheme for controlling the spreading of fluids [J. Feng (2012)]. The research presented in this dissertation spreads out across a wide range of physical phenomena (wicking, wetting, and capillarity), and involves a number of computational and experimental techniques, yet all of these projects are intrinsically united under a common theme: we want to better understand how simple fluids respond to small-scale complex surface structures as manifestations of surface-tension effects. We hope our findings can serve as building blocks for a larger scale endeavor of scientific research and engineering development. After all, the pursue of knowledge is most meaningful if the results improve the well-being of the society and the advancement of humanity.

capillarity

surface tension

wetting

wicking

Physics

THE DESIGN AND FABRICATION OF AUTONOMOUS POLYMER-BASED SURFACE TENSION-CONFINED MICROFLUIDIC PLATFORMS

Swickrath, Michael J.

January 2008

No description available.

microfluidics

surface tension

surface directed

hydrophilic

hydrophobic

USING GRADIENTS TO MANIPULATE WATER DROPLET BEHAVIOR ON COPPER AND ALUMINUM SURFACES

Alheshibri, Muidh Hamed

10 December 2013

No description available.

Physics

Mechanical Engineering

wettability

surface tension gradients

The surface tension of ⁴He from 0.3 K to T[lamda] /

Eckardt, James Rudolf

January 1973

No description available.

Physics

Surface tension

Superfluidity

Liquid helium

The stability of some molecular complexes in aqueous mixed solvents correlation with solvent surface tension.

Sun, Sy-rong.

January 1971

Thesis (Ph. D.)--University of Wisconsin--Madison, 1971. / Typescript. Vita. Description based on print version record. Includes bibliographical references.

Characterization of Organosilicone Surfactants and Their Effects on Sulfonylurea Herbicide Activity

Sun, Jinxia

05 April 1996

This research focused on the characterization of organosilicone surfactants and their effects on sulfonylurea herbicide activity. The project included efficacy tests, rainfastness studies in the greenhouse, radiotracer studies on herbicide uptake, fluorescent dye studies on surface deposition, and various measurements of physico-chemical properties. In measuring physico-chemical properties, a logistic dose response relationship was found between adjuvant concentration and contact angle on parafilm. An AsymSigR relationship existed between adjuvant concentration and surface tension for all the adjuvants. The organosilicones, Silwet L-77, Silwet 408, and Sylgard 309, and Kinetic (a blend of an organosilicone with a nonionic surfactant) gave equilibrium surface tension values around 20 dyne/cm and showed great spreading ability on the foliage of velvetleaf. With the conventional adjuvants, Agri-Dex, methylated soybean oil, Rigo oil concentration, and X-77, and Dyne-Amic (a blend of an organosilicone with a crop oil concentrate), surface tension was rarely below 28 dyne/cm and spreading ability was limited on velvetleaf. In addition, the organosilicone surfactant and Kinetic also lowered dynamic surface tension, which may improve droplet retention on leaf surfaces. The differences in physico-chemical properties between Kinetic and Dyne-Amic confirmed that carefully electing a co-adjuvant for an organosilicone blend is critical to avoid antagonism with trisiloxane molecules and retain the unique physico-chemical properties of organosilicone in the blends. Studies involving structurally-related organosilicones showed that the end structure in the trisiloxane hydrophilic group has little or no effect on surface tension, contact angle, spread pattern, herbicide uptake and translocation, and efficacy of primisulfuron on velvetleaf. It may be suggested that there is not a strict requirement to purify the end structure during the synthesis process, which is time consuming and expensive. When 14C-primisulfuron was combined with organosilicones or the blends, the uptake of 14C at 1 or 2 h after herbicide application was significantly higher than when combined with conventional adjuvants in velvetleaf. In the greenhouse, organosilicone surfactants greatly increased the rainfastness of primisulfuron in velvetleaf. The effect was immediate and dramatic, even when simulated rainfall was applied 0.25 h after treatment. In addition, herbicide efficacy on marginally susceptible weed species, velvetleaf and barnyardgrass, was significantly increased. A very complicated relationship exists between herbicides and adjuvants. The enhancement effects of adjuvants are often herbicide specific, weed species specific, and even environment specific. No one type of adjuvant functions well in all circumstances. Therefore, there is a need to understand the properties and functions of each class of adjuvants and locate the 'right' niche for each individual adjuvant. / Ph. D.

uptake

primisulfuron

efficacy

organosilicone

adjuvant

static surface tension

dynamic surface tension

contact angle

rainfastness