Micro-PIV Study Of Apparent Slip Of Water On Hydrophobic Surfaces

Asthana, Ashish

01 July 2008

The condition of no relative velocity of fluid past solid is termed as ‘no-slip boundary condition’. This condition is a general observation in fluid mechanics. However, several research groups have recently reported slip of water for surfaces with water repelling chemistry (referred to as hydrophobic surfaces). The effect has been attributed to disruption of H-bonding network of water molecules at such surfaces and resulting nucleation of dissolved gases and even reduced water density locally in absence of dissolved air. Slip of water on hydrophobic surfaces has been demonstrated to get amplified by high degree of roughness and patterning. Trapping of air in the surface asperities has been cited as the possible reason. The present work focuses on the study of effect of surface chemistry and roughness on flow behavior close to solid surfaces. Superhydrophobic surfaces have been generated by novel methods and wet-etching has been used to generate well-defined patterns on silicon surfaces. For flow characterisation, a micrometre resolution Particle Image Velocimetry (micro-PIV) facility has been developed and flow measurements have been carried out with a spatial resolution of less than 4 µm. It has been found from the experiments that flow of water on smooth surfaces, with or without chemical modification, conforms to the no-slip within the resolution limits of experiments. Deviation is observed in case of rough and patterned hydrophobic surfaces, possibly because of trapped air in asperities. Total Internal Reflection experiments, used to visualise the air pockets, confirmed the trapping of air at asperities. Diffusion of air out of the crevices seems to be the limiting factor for the utility of these surfaces in under-water applications.

Micro Particle Image Velocimetry

Hydrophobic Surfaces

Surface Chemistry

Machine Engineering

Hydrophobic Surfaces - Apparent Slip

Micro-PIV

Surfaces

Machine Engineering

The influence of preadsorbed milk proteins on adhesion of Listeria monocytogenes to silica surfaces

Al-Makhlafi, Hamood K.

01 August 1994

β-lactoglobulin (β-Lg), bovine serum albumin (BSA), α-lactalbumin (α-Lac), and β-casein were adsorbed onto silanized silica surfaces of low and high hydrophobicity for 8 h, and β-Lg and BSA for 1 h. The surfaces were incubated in buffer for 0, 5, 10, or 15 h and then contacted with Listeria monocytogenes for 3 h. Cell adhesion was quantified using image analysis. Following 8 h of protein contact, adhesion to both surfaces was greatest when β-Lg was present and lowest when BSA was present. Preadsorption of α-Lac and β-casein showed an intermediate effect on cell adhesion. Adsorption of β-Lg for 1 h resulted in lower numbers of cells adhered as compared to the 8 h adsorption time, while the opposite was observed with BSA, but adhesion to BSA was observed to decrease slowly with film age to values comparable to the 8 h tests. The adsorption of BSA and β-Lg to both surfaces was also carried out where each protein was allowed to contact the surface in sequence and simultaneously. In sequential tests performed with an 8 h contact/protein, cell numbers on each surface were near that expected for the bare hydrophobic surface when β-Lg contact preceded introduction of BSA, whereas adhesion was reduced to values below that expected for the bare hydrophilic surface when BSA preceded β-Lg contact. In short-term sequential tests (1 h contact/protein), adhesion was lower than that recorded on bare hydrophilic surfaces in each case. Adhesion to each surface following contact with an equimolar mixture of β-Lg and BSA was lower than that measured on the bare hydrophilic surface in each case, with adhesion following 1 h contact being greater than that following 8 h contact. Adhesion following competitive adsorption was greater to hydrophobic than to hydrophilic surfaces. These results were explained with reference to the surface passivating character of BSA, and its ability to rapidly attain a nonexchangeable state upon adsorption, relative to β-Lg. / Graduation date: 1995

Milk proteins

Listeria monocytogenes

Hydrophobic surfaces

Bacteria -- Adhesion

Capillary Migration of Large Confined Drops in Non-wetting Wedges

Torres, Logan John

28 March 2019

When confined within containers or conduits, drops and bubbles migrate to regions of minimum energy by the combined effects of surface tension, surface wetting, system geometry, and initial conditions. Such capillary phenomena are exploited for passive phase separation operations in micro-fluidic devices on earth and macro-fluidic devices aboard spacecraft. Our study focuses on the migration and ejection of large inertial-capillary drops confined between tilted planar hydrophobic substrates. In our experiments, the brief nearly weightless environment of a drop tower allows for the study of such capillary dominated behavior for up to 10 mL water drops with migration velocities up to 12 cm/s. We control ejection velocities as a function of drop volume, substrate tilt angle, initial confinement, and fluid properties. We then demonstrate how such geometries may be employed as passive no-moving-parts droplet generators for very large drop dynamics investigations. The method is ideal for hand-held non-oscillatory drop generation for fun, educational, and insightful astronaut demonstrations aboard the International Space Station.

Fluid mechanics -- Research

Microfluidics

Drops

Hydrophobic surfaces

Fluid Dynamics

Experimental investigation of the influence of surface energy and pore fluid characteristics on the behavior of partially saturated coarse-grained soils

Cutts, Ross Evan.

January 2009

Thesis (M. S.)--Civil and Environmental Engineering, Georgia Institute of Technology, 2010. / Committee Chair: Susan E. Burns; Committee Member: Glenn J. Rix; Committee Member: J. Carlos Santamarina. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Fundamentals, preparation, and characterization of superhydrophobic wood fiber products

Yang, Hongta

05 May 2008

In this study, we developed a facile method for preparing a superhydrophobic paper surface using a layer-by-layer deposition of polydiallyldimethylammonium chloride (polyDADMAC) and silica particles, followed by a fluorination surface treatment with 1H,1H,2H,2H-perfluorooctyltriethoxysilane (POTS, CF3(CF2)5CH2CH2Si(OC2H5)3). The wood fiber products prepared in this study had contact angles of water greater than 150 degree and sliding angles less than 5 degree. Besides their high water repelling property, the superhydrophobic paper products kept a high tensile strength at high relative humidity condition. The superhydrophobic paper products also showed high resistance to bacterial contamination.

Superhydrophobic

Hydrophobic surfaces

Paper products

Surface roughness

Paper coatings

Environmental analysis of biologically inspired self-cleaning surfaces

Raibeck, Laura

January 2008

Thesis (M. S.)--Mechanical Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Bert Bras; Committee Member: David Rosen; Committee Member: Jeannette Yen

Part I: Isocratic and gradient elution reversed-phase liquid chromatography for the estimation of the hydrophobicity parameter log K'W applications to newer generation stationary phases. Part II: Planar electrochromatographic instrumental design and results /

Tate, Peter Anthony. Dorsey, John G.

January 2005

Thesis (Ph. D.)--Florida State University, 2005. / Advisor: Dr. John G. Dorsey, Florida State University, College of Arts and Sciences, Dept. of Chemistry and Biochemistry. Title and description from dissertation home page (June 15, 2005). Document formatted into pages; contains xiv, 112 pages. Includes bibliographical references.

Fundamentals, preparation, and characterization of superhydrophobic wood fiber products

Yang, Hongta.

January 2008

Thesis (M. S.)--Chemical Engineering, Georgia Institute of Technology, 2008. / Committee Chair: Yulin Deng; Committee Member: Jeffery S. Hsieh; Committee Member: Sujit Banerjee; Committee Member: Zhong Lin Wang.

Non-Newtonian Drop Impact on Textured Solid Surfaces: Bouncing and Filaments Formation

Al Julaih, Ali

04 1900

This work uses high-speed video imaging to study the formation of filaments, during impact and rebounding of drops with polymer additives. We use PEO of different concentrations from 10 to 1000 ppm and study how drops rebound from various different surfaces: superhydrophilic, hydrophilic, hydrophobic, and superhydrophobic. Bouncing occurs for all surfaces at low impact velocities. We specifically focus on the phenomenon of the generation of polymer filaments, which are pulled out of the free surface of the drop during its rebounding from micro-pillared or rough substrates. We map the parameter regime, in terms of polymer concentration and impact Weber number, where the filaments are generated in the most repeatable manner. This occurs for regularly pillared surfaces and drops of 100 ppm PEO concentrations, where numerous separated filaments are observed. In contrast, for superhydrophobic coatings with random roughness the filaments tend to merge forming a branching structure. Impacts on inclined surfaces are used to deposit the filaments on top of the pillars for detailed study.

drop impact

non-newtonian liquids

hydrophobic surfaces

polyethylene oxide

bouncing

filaments

Maintaining Underwater Cassie State for Sustained Drag Reduction in Channel Flow

Dilip, D

January 2016

Water droplets tend to bead up on rough or textured hydrophobic surfaces by trapping air on the crevices underneath resulting in “Cassie” state of wetting. When a textured hydrophobic surface is immersed in water, the resulting underwater “Cassie” state can lead to significant drag reduction. The entrapped air pockets act as shear free regions and the composite interface consisting of alternate no slip and no shear regions thus formed can deliver substantial drag reduction during flow. The magnitude of drag reduction depends not only on the fractional coverage of air on the surface, but also on the size of the air pockets, with larger sized air pockets facilitating larger drag reduction. It is a common observance that Lotus leaf when kept immersed in water for a few minutes loses its water repellency due to the loss of entrapped air on the surface. Underwater Cassie state on textured hydrophobic surfaces is also not sustainable because of the depletion of air pockets caused by the diffusion of trapped air into water. This causes the drag reduction to diminish with time. Rate of diffusion of air across the water–air interface depends on the concentration gradient of air across the interface. Under flow conditions, removal of entrapped air is further enhanced by convection, leading to more rapid shrinkage of the air pockets. In order to sustain the Cassie state, it is thus necessary to continuously supply air to these air pockets. In this work, we explore the possibility of supplying air to the cavities on the textured surface inside a microchannel by controlling the solubility of air in water close to the surface. The solubility is varied by i) Controlling the absolute pressure inside the channel and ii) Localized heating of the surface To trap uniform air pockets, a textured surface containing a regular array of blind holes is used. The textured surface is generated by photo etching of brass and is rendered hydrophobic through a self-assembled monolayer. The sustainability of the underwater Cassie state of wetting on the surface is studied at various flow conditions. The air trapped on the textured surface is visualized using total internal reflection based technique, with the pressure drop (or drag) being simultaneously measured. Water which is initially saturated with air at atmospheric conditions, when subjected to sub-atmospheric pressures within the channel becomes supersaturated causing the air bubbles to grow in size. Further growth causes the bubbles to merge and eventually detach from the surface. The growth and subsequent merging of the air bubbles leads to a substantial increase in the pressure drop because as the air pockets grow in size, they project into the flow and start obstructing the flow. On the other hand, a pressure above the atmospheric pressure within the channel makes the water undersaturated with air, leading to gradual shrinkage and eventual disappearance of air bubbles. In this case, the air bubbles do cause reduction in the pressure drop with the minimum pressure drop (or maximum drag reduction) occurring when the bubbles are flush with the surface. The rate of growth or decay of air bubbles is found to be significantly dependent on the absolute pressure in the channel. Hence by carefully controlling the absolute pressure, the Cassie state of wetting can be sustained for extended periods of time. A drag reduction of up to 15% was achieved and sustained for a period of over 5 hours. Temperature of water also influences the solubility of air in water with higher temperatures resulting in reduced solubility. Thus locally heating the textured hydrophobic surface causes the air bubbles to grow, with the rate of growth being dependent on the heat input. The effect of trapped air bubbles on thermal transport is also determined by measuring the heat transfer rate through the surface in the presence and absence of trapped air bubbles. Even though the trapped air bubbles do cause a reduction in the heat transfer coefficient by about 10%, a large pressure drop reduction of up to 15% obtained during the experiments helps in circumventing this disadvantage. Hence for the same pressure drop across the channel, the textured hydrophobic surface helps to augment the heat transfer rate. The experiments show that, by varying the solubility of air in water either by controlling the pressure or by local heating, underwater Cassie state of wetting can be sustained on textured hydrophobic surfaces, thus delivering up to 15% drag reduction in both cases for extended periods of time. The results obtained hold important implications towards achieving sustained drag reduction in microfluidic applications.

Underwater Cassie State

Wenzel State

Super-Hydrophobic Surfaces

Artificial Super-Hydrophobic Surfaces

Atmospheric Pressure

Hydrophobic Microchannels

Superhydrophobic Surface

Microchannel

Drag Reduction

Sustained Drag Reduction

Mechanical Engineering