Laser generation and applications of micron and submicron scale features on metals

Lloyd, Robert William

January 2011

This thesis describes the formation of and applications of self-assembled structures on metals. Primarily the focus of this PhD project is on the formation of surfaces structures on stainless steel (AISI 304) but other metals have been studied. Laser generated surface structures have been applied to the modification of wettability and reflectivity with a view towards developing these processes for industrial applications. Compared to conventional techniques for the modification of wettabililty, lasers offer the advantage of being a relatively simple technique for the modification of surface structure, reducing the need for complex processes. It is hoped that investigations into the reduction of surface reflectivity will have applications in the conversion of solar energy into useable power in the form of solar thermal energy. The production of self assembled structures is demonstrated using diode pumped solid state (DPSS) Nd:YVO4 lasers operating at wavelengths of 532 and 1064 nm. It is shown that the production of surface microstructures is highly dependant on the correct laser fluence and requires multiple pulses and processing passes. At 1064 nm wavelengths, it has been found highly reproducible surface structures can be formed by carefully controlling laser fluence and scanning speed while keeping the optical arrangement relatively simple. In addition to microstructure formation, the use of ultrafast femtosecond lasers, operating at 400 and 800 nm wavelengths has verified the production of laser induced periodic surface structures. Additionally, the stationary method used to produce these surfaces has been adapted to cover large surface areas with sub wavelength ripple structures with periods of ~295nm and 600nm. Applications of laser surface microstructures on metals have been studied in an effort to produce hydrophobic and superhydrophobic surfaces on metals. It has been found that the roughness change produced by laser processing induces composite wetting when water droplets are introduced to the surface. Contact angle measurements and small angle XRD analysis of laser processed stainless steel (AISI 304) have shown that surface wettability decreased over a period of approximately one month, leading to steady contact angles of over 140°. This is attributed to the formation of a magnetite (Fe3O4) oxide layer in the period after laser processing. The effect of surface microstructure on surface reflectivity has also been studied. It was found that laser induced surface microstructures on copper can decrease surface reflectivity by almost 90%. A comparative study of the effects of surface roughness and chemistry on the optical absorption of copper is given, finding that these surfaces are competitive with contemporary coatings.

669

Tubules composed of non-structural protein NS1 of african horsesickness virus as system for the immune display of foreign peptides

Lacheiner, Karen

09 July 2008

Non-structural protein, NS1 of African horse sickness virus is a hydrophobic protein of 63 kDa that spontaneously assembles into highly distinct tubular structures when expressed in mammalian or insect cells. The spontaneous assembly of these proteins into a predictable multimeric structure, high levels of expression and ease of purification make this protein an ideal candidate for the immune display of foreign peptides. The potential of such a display system has been investigated for BTV NS1 that is able to successfully elicit both a humoral and a cellular immune response against inserted peptides. The aims of this study were to investigate both the stability of the AHSV NS1 particulate structure after insertion of peptides as well as the antigenicity and immunogenicity of the peptides presented in this system. Two overlapping regions consisting of 40 and 150 amino acids, and which correspond to a neutralising region identified within the AHSV major neutralising protein VP2, were inserted into an internal site in NS1. This site offered the best surface display of inserted peptides on the tubular structures. An enhanced green fluorescent protein, 240 amino acids long, was also inserted into the NS1 protein. Sucrose gradient analysis of the recombinant proteins indicated that the majority of the baculovirus expressed chimeric proteins formed particulate structures with a sedimentation value similar to that of the native NS1 protein. This was confirmed by transmission electron microscopic analysis, which clearly showed that all the chimeric proteins assembled into tubular structures similar to those observed for AHSV NS1 proteins. Furthermore, fluorescence analysis of sucrose gradients of NS1/eGFP also showed high levels of fluorescence that corresponded directly to particle formation. Not only do the inserts remain functional but are also presented successfully on the surface of the intact NS1 tubule structure. The potential of the NS1 vector to efficiently present peptides to the immune system was subsequently investigated. The serums generated against these chimeric proteins in guinea pigs were tested against chimeric constructs, the baculovirus expressed inserts (for eGFP) and the inserts presented on other presentation vectors. Western blot analysis showed that most of the serums generated against the chimeric proteins contained antibodies not only against the chimeric proteins but antibodies that reacted specifically with the inserted peptides on their own or on another presentation system. Preliminary immune studies seem to indicate that the humoral immune response elicited by the chimeric NS1 proteins is predominantly against the inserts. The inserts are successfully presented to the immune system on the surface of the NS1 vector and are able to elicit the production of antibodies with the potential to provide a protective immune response. / Dissertation (MSc (Genetics))--University of Pretoria, 2010. / Genetics / unrestricted

African horse sickness (AHS)

Ns1

Hydrophobic protein

UCTD

Investigating Mechanisms Underlying Hydrophobic Interaction Between Extended Surfaces in Aqueous Environments

Pillai, Sreekiran

11 1900

The hydrophobic interaction refers to a mutually attractive force experienced by hydrophobic surfaces or molecules across water. At the molecular scale, it drives the selfassembly of lipid vesicles and micelles and accelerates interfacial chemical reactions. At the macroscale, it confers upon numerous plants and insects the ability to repel water and is harnessed in practical applications, such as water-proofing and desalination. However, despite its ubiquity and significance, mechanistic insights into the hydrophobic interaction between macroscopic surfaces remain unclear. A significant body of experimental data on surface force measurements exists, which were obtained following this protocol: hydrophobic molecules (typically organosilanes) are physisorbed onto molecularly smooth mica films that are glued onto transparent rigid silica discs and driven towards each other while measuring forces and distances. We developed a protocol for functionalizing mica surfaces with perfluorodecyltrichlorosilane (FDTS) to achieve robust, ultra-smooth hydrophobic surfaces. Then we investigated the consequences of nuclear quantum effects (NQEs) in water on the hydrophobic interaction. Whereas NQEs are known to influence physical and chemical properties of water, their impact on the hydrophobic interaction has remained largely unexplored. We find that the attractive forces between FDTS-coated mica surfaces were ~ 10% higher in light water (H2O) than in heavy water (D2O) even though macroscopic measurables, such as the interfacial tensions and contact angles are indistinguishable. This is the first-ever experimental demonstration of nuclear quantum effects at play in modulating hydrophobic surface forces. Towards practical applications, we investigated the partitioning of small, amphiphilic molecules onto our molecularly smooth FDTS-coated mica films. These scenarios are relevant in wastewater treatment, bioresource processing, fermenter broths, and food & beverage industries. Water-soluble short chain alcohols (ethanol) readily partitioned onto FDTS surfaces and remained attached onto the surface. The presence of alcohols was confirmed by surface force measurements, contact angle goniometry of water drops, and gas chromatography. We investigated protocols for characterizing fouled surfaces and cleaning them. These protocols were tested on realistic desalination membranes and proved effective. Thus, our findings could be used to develop robust protocols for characterizing membrane fouling and cleaning protocols in various separation processes.

Hydrophobicity

Surface forces

Hydrophobic Interaction

Nuclear quantum effects

Membrane failure

Application of Argon Plasma Technology to Hydrophobic and Hydrophilic Microdroplet Generation in PDMS Microfluidic Devices

Graham, Brennan P

01 March 2017

Abstract Application of Argon Plasma Technology to Hydrophobic and Hydrophilic Microdroplet Generation in PDMS Microfluidic Devices Brennan Graham Microfluidics has gained popularity over the last decade due to the ability to replace many large, expensive laboratory processes with small handheld chips with a higher throughput due to the small channel dimensions [1]. Droplet microfluidics is the field of fluid manipulation that takes advantage of two immiscible fluids to create droplets from the geometry of the microchannels. This project includes the design of a microfluidic device that applies the results of an argon plasma surface treatment to polydimethylsiloxane (PDMS) to successfully produce both hydrophobic and hydrophilic surfaces to create oil in water (O/W) and water in oil (W/O) microdroplets. If an argon plasma surface treatment renders the surface of PDMS hydrophilic, then O/W microdroplets can be created and integrated into a larger microdroplet emulsion device. The major aims of this project include: (1) validating previously established Cal Poly lab protocols to produce W/O droplets in hydrophobic PDMS microdroplet generators (2) creating hydrophilic PDMS microdroplet generators (3) making oil in water droplets in hydrophilic PDMS microdroplet generators (4) designing a multilayer microfluidic device to transfer W/O droplets to a second hydrophilic PDMS microdroplet generator v W/O droplets were successfully created and transferred to a second hydrophilic PDMS device. The hydrophilic PDMS device also produced O/W droplets in separate testing from the multilayered microfluidic PDMS device. The ultimate purpose of this project is to create a multilayer microdroplet generator that produces water in oil in water (W/O/W) microdroplet emulsions through a stacked device design that can be used in diagnostic microdroplet applications. Thesis Supervisor: Dave Clague Title: Professor of Biomedical Engineering

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

Application of Extended DLVO Theory: Modeling of Flotation and Hydrophobicity of Dodecane

Mao, Laiqun

13 November 1998

The extended DLVO theory was used to develop a flotation model by considering both hydrodynamic and surface forces involved in the process. A stream function was used to estimate the kinetic energies for thinning the water films between bubbles and particles, which were compared with the energy barriers, created by surface forces, to determine the probability of adhesion. A general expression for the probability of detachment was derived from similar mechanism for chemical reaction, and the kinetic energy for detachment was estimated with French and Wilson's model. The hydrophobic force parameter (K132) calculated from the rate constants of single bubble flotation tests showed that, K132 for bubble-particle interaction were close to the geometric means of K131 for particle-particle interactions and K232 for bubble-bubble interaction, indicating that the combining rules developed for dispersion forces may be useful for hydrophobic forces. The model was used to predict flotation results as functions of several important parameters such as contact angle, double-layer potentials, particle size, bubble size, etc. The predictions were consistent with experience, and could be explained in view of the various subprocesses considered in the model development. Furthermore, the model suggested optimum conditions for achieving the maximum separation efficiency. The extended DLVO theory was also used to determine the hydrophobic force between two oil/solution interfaces from the equilibrium film thicknesses of dodecylammonium chloride (RNH3Cl) solutions obtained using Thin Film Balance (TFB) technique. The results showed that, the oil droplets were inherently hydrophobic, and the hydrophobic force played an important role in the stability of emulsions. This force decreased with increasing surfactant concentration, and also changed with pH and the addition of electrolyte. The interfacial area occupied by molecules indicated that, the dodecane molecules might present between two surfactant ions at interface, thus the hydrophobicity of oil/solution interface was less sensitive to the addition of the surfactant than that of air/solution interface. Thermodynamic analysis suggested that, there might exist a relationship between the interfacial hydrophobicity and the interfacial tension. / Ph. D.

Dodecane

Flotation Modeling

Extended DLVO theory

Hydrophobic Force

Suspended dsDNA/Rad51 on super-hydrophobic devices: Raman spectroscopy characterization

Morello, Maria Caterina

22 November 2018

The novel method herein proposed, aims to study Deoxyribonucleic acid (DNA) and Rad51 repair protein in its resting state after their interaction by using a combination of biological preparation and physical measures. Rad51 is a highly conserved protein; it is involved in eukaryotes genome stability and can interact with single strand (ss) and double strands (ds) DNA. In our work, a droplet of the solution containing the dsDNA/Rad51 complexes was deposited on micro-fabricated super-hydrophobic substrates (SHS) to obtain self-organized and suspended fibers. The silicon-based SHS were designed to incorporate a regular circular array of pillars and to maintain a high contact angle with the drop. The samples were let dehydrate at controlled temperature and humidity conditions. At the end of the buffer evaporation process, non-suspended material and salt excess are concentrated on the top of a few micro-pillars in a limited area (drop residual) of the device while ordered and self-assembled DNA/Rad51 fibers are suspended between micro-pillars. To find the ideal conditions to obtain and suspend the nucleic acid/protein complexes, several parameters were investigated: saline buffer, DNA and protein concentrations were widely titrated and showed a significant effect on the biomolecule suspension on SHS. The samples were then preliminarily checked by microscopy techniques and then described by the Raman spectra acquired. Several techniques were used: optical microscopy, Energy Dispersive X-Ray Spectroscopy (EDAX), Scanning Electron Microscopy (SEM) and Raman Spectroscopy. Protein expressions, DNA suspension, micro-fabrication and characterization were all performed in KAUST Core Labs and Structural Molecular Imaging Light Enhanced Spectroscopies (SMILEs) Lab. The novel approach presented in this work is highly multidisciplinary and comprises physical measurements (Raman spectroscopy and EM imaging), chemistry and biology. In future the method can be used further expanded supporting the data with HRTEM direct imaging to elucidate the nucleic acids/proteins behavior in the multiple phases of the genome repair processes. Also, it and can serve as a fingerprint of the biological molecules involved in biological interactions, their localization and structural characterization, providing a new tool for structural analysis, screening and diagnostics.

Super-Hydrophobic

Rad51 Protein

DNA

Raman Spectroscopy

SEM

SHS

Experimental Study of Chamber Volume Effect on Bubble Growth from Orifice Plates Submerged in Liquid Pools

Gokhale, Omkar S.

09 July 2019

No description available.

Mechanical Engineering

Bubble dynamics

Chamber volume

Hydrophilic

Hydrophobic

Study on Polyelectrolyte Brushes on Silicone Rubber And The Influence Of Hydrophobic Recovery

Tong, Zifeng

28 April 2021

No description available.

Materials Science

Probing Surface Charge Densities of Common Dielectrics

Alghonaim, Abdulmalik

07 1900

The value of the surface charge density of polypropylene reported in literature has a three order of magnitude discrepancy. Nauruzbayeva et al report a 0.7nCcm−2 as the surface charge density of polypropylene as measured using the charge of electrified droplets[1]. Meagher and Craig reported result 111nCcm−2 as estimated by electric double layer theory from colloidal probe Atomic force microscopy (AFM) force spectroscopy [2]. We show that oxidation of hydrophobic surfaces as a potential mechanism in origin of these surface charges. Using colloidal probe AFM We measured the surface charge densities of Teflon AF, perfluorodecanethiol, Perfluorodecyltrichlorosilane(FDTS), Octadecyltrichlorosilane, polystyrene, and polypropylene. Also, The pH dependence of the surface charge density for FDTS was studied and it shows the behavior expected of a weak acid in response to pH. We suspect that the origin of the surface charges is mostly likely impurities or surface oxidation. We conclude that the electrometer and dispensed droplets approach cannot detect these charges because of the process of de-wetting all the surface be neutralized to maintain charge neutrality. This explanation supports Nauruzbayeva et al claims about surface bound charges[1].

hydrophobic surface

surface charge density

electrification

Atomic force microscopy