Energy Distribution of Sputtered Neutral Atoms from a Multilayer Target

Bigelow, Alan W.

08 1900

Energy distribution measurements of sputtered neutral particles contribute to the general knowledge of sputtering, a common technique for surface analysis. In this work emphasis was placed on the measurement of energy distribution of sputtered neutral atoms from different depths. The liquid Ga-In eutectic alloy as a sample target for this study was ideal due to an extreme concentration ratio gradient between the top two monolayers. In pursuing this study, the method of sputter-initiated resonance ionization spectroscopy (SIRIS) was utilized. SIRIS employs a pulsed ion beam to initiate sputtering and tunable dye lasers for resonance ionization. Observation of the energy distribution was achieved with a position-sensitive detector. The principle behind the detector's energy resolution is time of flight (TOF) spectroscopy. For this specific detector, programmed time intervals between the sputtering pulse at the target and the ionizing laser pulse provided information leading to the energy distribution of the secondary neutral particles. This experiment contributes data for energy distributions of sputtered neutral particles to the experimental database, required by theoretical models and computer simulations for the sputtering phenomenon.

Surfaces (Technology) -- Analysis.

Sputtering (Physics)

surface analysis

sputtering

energy distribution

Patterned and switchable surfaces for biomaterial applications

Hook, Andrew Leslie, andrew.hook@flinders.edu.au

January 2008

The interactions of biomolecules and cells at solid-liquid interfaces play a pivotal role in a range of biomedical applications and have hence been studied in detail. An improved understanding of these interactions results in the ability to manipulate biomolecules and concurrently cells spatially and temporally at surfaces with high precision. Spatial control can be achieved using patterned surface chemistries whilst temporal control is achieved by switchable surfaces. The combination of these two surface properties offers unprecedented control over the behaviour of biomolecules and cells at the solid-liquid interface. This is particularly relevant for cell microarray applications, where a range of biological processes must be duly controlled in order to maximise the efficiency and throughput of these devices. Of particular interest are transfected cell microarrays (TCMs), which significantly widen the scope of microarray genomic analysis by enabling the high-throughput analysis of gene function within living cells Initially, this thesis focuses on the spatially controlled, electro-stimulated adsorption and desorption of DNA. Surface modification of a silicon chip with an allylamine plasma polymer (ALAPP) layer resulted in a surface that supported DNA adsorption and sustained cell attachment. Subsequent high density grafting of poly(ethylene glycol) (PEG) formed a layer resistant to biomolecule adsorption and cell attachment. PEG grafted surfaces also showed significantly reduced attachment of DNA with an equilibrium binding constant of 23 ml/mg as compared with 1600 ml/mg for ALAPP modified surfaces. Moreover, both hydrophobic and electrostatic interactions were shown to contribute to the binding of DNA to ALAPP. Spatial control over the surface chemistry was achieved using excimer laser ablation of the PEG coating which enabled the production of patterns of re-exposed ALAPP with high resolution. Preferential electro-stimulated adsorption of DNA to the ALAPP regions and subsequent desorption by the application of a negative bias was observed. Furthermore, this approach was investigated for TCM applications. Cell culture experiments demonstrated efficient and controlled transfection of cells. Electro-stimulated desorption of DNA was shown to yield enhanced solid phase transfection efficiencies with values of up to 30%. The ability to spatially control DNA adsorption combined with the ability to control the binding and release of DNA by application of a controlled voltage enables an advanced level of control over DNA bioactivity on solid substrates and lends itself to biochip applications. As an alternative approach to surface patterning, the fabrication and characterisation of chemical patterns using a technique that can be readily integrated with methods currently used for the formation of microarrays is also presented. Here, phenylazide modified polymers were printed onto low fouling ALAPP-PEG modified surfaces. UV irradiation of these polymer arrays resulted in the crosslinking of the polymer spots and their covalent attachment to the surface. Cell attachment was shown to follow the patterned surface chemistry. Due to the use of a microarray contact printer it was easily possible to deposit DNA on top of the polymer microarray spots. A transfected cell microarray was generated in this way, demonstrating the ability to limit cell attachment to specific regions and the suitability of this approach for high density cell assays. In order to allow for the high-throughput characterisation of the resultant polymer microarrays, surface plasmon resonance imaging was utilised to study the adsorption and desorption of bovine serum albumin, collagen and fibronectin. This analysis enabled insights into the underlying mechanisms of cell attachment to the polymers studied. For the system analysed here, electrostatic interactions were shown to dominate cellular behaviour.

surface analysis

biomolecular manipulation

transfection

microarray

surface plasmon resonance imaging

Optimisation of boric sulphuric acid anodising based processes for metal-to-metal adhesive bonding

Yendall, Keith A.

January 2003

No description available.

673.72258

Spectroscopy surface analysis of paracetamol and paracetamol and excipient systems

Mohd Zaki, Hamizah

January 2011

A detailed, fundamental understanding of the surface properties of molecular crystals and their interaction with adsorbing molecules (e.g. excipients) is important for tailoring the stability of formulations and the bioavailability of Active Pharmaceutical Ingredient (APIs). Few fundamental experimental studies with surface sensitive probes have been carried out for organic molecular crystals. X-ray photoelectron spectroscopy (XPS) is an established surface analysis method in the fields of adsorption, catalysis and surface chemistry of inorganic crystals. It has high surface sensitivity, probing approximately the top 1-3 nm of a crystal, and allows surface elemental analysis combined with the determination of the chemical state of the elements. To explore the possibilities and limitations of XPS for the surface characterisation of molecular crystal systems, investigation has been made on a range of paracetamol systems, three different poloxamers and blends of paracetamol with poloxamer 188. It was found by investigations of a range of polycrystalline paracetamol forms that the C1s, N1s and O1s core level emissions from the amide group of paracetamol allow to quantify, for the first time, the influence of surface contamination and adsorbed species on the paracetamol XPS data. Results of quantitative XPS analyses must be critically evaluated taking the material and energy-specific escape depth of the photoelectron signals into account. Analysis of the polycrystalline powder samples, including two different polymorphs and various partially amorphous forms of paracetamol, indicated that the core-level shifts associated with varying intermolecular interactions do not perturb the local electronic structure variations in paracetamol enough to become detectable through chemical shifts in the core level photoemission spectra. Subsequently, large, high quality single crystals of the monoclinic form I (with facet diameters between ~5 and ~10 mm) were obtained from different solvents (methanol, ethanol, acetone) to examine the influence of the crystallisation medium on the surface properties. Small spot XPS analysis was performed in several areas across facets to examine the possible influence of roughness and other lateral inhomogeneities. Careful curve-fitting of all results reveals only minor variations in the XPS data as a function of facet orientation, crystallisation medium or degree of crystallinity. Moreover, results indicate that any variations seen in XPS data very likely stem from low-level surface contamination, which is very difficult to avoid, even in a clean-room laboratory environment. In fact, the results indicate that the level of surface contamination depends significantly on the crystallisation apparatus cleanliness. Even minute concentrations of surface active components in the solutions, i.e. below the detection level of techniques for routine analytical methods, are likely to cause significant surface concentrations on crystal facets emersed from the solutions. The study thus highlights the paramount importance of microscopic surface cleanliness when assessing macroscopic facet-specific phenomena such as contact angles. Finally, XPS was employed to analyse milled and physical mixtures of paracetamol with poloxamer 188 at different percent. At minimum mass percentages poloxamer 188 adsorbs on the paracetamol surfaces; in the presence of poloxamer 188 excess the conformation of adsorbed poloxamer on the paracetamol surface changes. Studies of radiation damage on the poloxamer samples were performed both for several pure polxamers as well as for milled mixtures with paracetamol. They allowed the proposal of radiation-induced degradation mechanisms.

615.19

Analysis of a murine lymphocyte proliferation-associated antigen (MALA-2) : the murine homolog of the human ICAM-1 molecule

Baker, Brett Hugh James

January 1989

MALA-2 (Murine Lymphocyte Activated Antigen-2) is a murine cell surface antigen that is detected at high concentration on activated, proliferating lymphocytes, but only weakly on resting lymphocytes. It is thought to play an important role in lymphocyte activation since the rat monoclonal antibody YN1/1.7.4 which recognizes MALA-2 is capable of inhibiting the mixed lymphocyte reaction. Considering the central role of lymphocyte activation to the generation and maintenance of the immune response, I undertook the purification and biochemical characterization of MALA-2. In these studies, MALA-2 was isolated and purified to homogeneity using immobilized YN1/1.7.4 monoclonal antibody and sodium docecylsulphate-polyacrylamide gel electrophoresis. Biochemical characterization studies revealed that MALA-2 is a Mr 95-100 kD glycoprotein containing a protein backbone of approximately 66 kD, and N-linked carbohydrate chains amounting to a Mr of approximately 35 kD. Two dimensional gel electrophoresis suggested that MALA-2 has an isoelectric point of 4.9. Although it was previously suspected that MALA-2 might be associated with the transferrin receptor on the cell surface, this was shown not to be the case on NS-1 cells. Additionally, ³²P-orthophosphate labelling of MALA-2 on NS-1 or MBL-2 cells could not be detected. Finally, the partial amino acid sequence of MALA-2 was determined by sequencing trypsin-generated peptides from purified MALA-2. Computer-assisted homology comparisons of the MALA-2 partial amino acid sequences with other known sequences showed that MALA-2 shared its most consistent homology with a class of proteins known as the immunoglobulin superfamily. Subsequent to this study, the partial amino acid sequences obtained within this study were used to construct oligonucleotide probes. These probes were used for the screening of cDNA libraries, facilitating the successful cloning of the MALA-2 gene. This, in turn, resulted in the identification of MALA-2 as the murine counterpart of the human ICAM-1 molecule, a protein known to play a significant role in intercellular adhesion and lymphocyte activation within the immune system. Significantly, results obtained from the biochemical characterization of MALA-2 carried out in this thesis have been confirmed by the subsequent nucleotide sequence data from the cloning of MALA-2. / Medicine, Faculty of / Pathology and Laboratory Medicine, Department of / Graduate

Antigens -- Analysis

Lymphocyte transformation

Antigens, Surface -- analysis

Lymphocyte Activation

Comparison between endocytosis and intracanalicular sequestration of cell-surface antigens in human platelets

Jennings, Brent

January 1992

Human platelets respond to various macromolecules in the plasma. Uptake of specific ligands, and antibodies to various epitopes on the platelet plasma membrane, has been observed. The platelet canalicular system has been shown to be involved with this uptake. Recently, investigators have speculated on the role of endocytosis in platelets to account for the presence of plasma proteins such as fibrinogen and immunoglobulin within platelet organelles. Antibodies binding to cell-surface antigens on platelets can lead to a redistribution of these antigens. When antibodies, specific for platelet cell-surface receptors, bind to platelets they may either undergo endocytosis into intracellular vacuoles, or may merely become sequestered within the canalicular system of platelets. The present study investigated whether endocytosis occurs in platelets. Such a process would lead to the endocytic uptake of a fluid-phase marker and would involve internalization and recycling of cell surface membrane. A fluid-phase marker (FITC-dextran) was used to measure any constitutive endocytic activity. In addition, a suitable membrane marker was used to determine whether membrane internalization occurred. This involved a technique whereby radioactive galactose was covalently attached to cell-surface glycoconjugates. A monoclonal antibody to the platelet receptor, GPIIbIIIa, was used in conjunction with the membrane marker in order to determine if membrane internalization was involved during the subsequent redistribution of the receptor-antibody complex. Immunocytochemical techniques using electron-dense probes were employed to localise the sites to which this receptor-antibody complex became redistributed. In comparison with reported rates of endocytic uptake of fluid-phase marker in other cell types, no significant endocytic activity could be detected with platelets, after taking their relatively small volume into account. Similarly, membrane internalization was not detected with resting platelets. Following challenge of the platelets with anti-GPIIbIIIa antibody, no membrane internalization could be measured during redistribution of the receptor-antibody complex. The compartment to which the receptor-antibody complex was redistributed could be identified morphologically as the canalicular system. The present data provide evidence for a process of sequestration of receptor-antibody in the canalicular system of resting platelets. It remains possible that other mechanisms exist within the platelet system for uptake of extracellular material as this study dealt exclusively with the platelet response to a specific antibody. These results may have implications with respect to the interaction of platelets with anti-platelet antibodies in the normal state, as well as with clinical disorders involving elevated levels of platelet-associated IgG. As far as can be deduced from the available literature, these data represent the first use of a covalent membrane marker in conjunction with uptake of macromolecules to study endocytic events in human platelets.

Antigens, Surface - analysis

Blood platelets - Cytology

Endocytosis

Medical Biochemistry

The Role of Cerium Redox State in the SOD Mimetic Activity of Nanoceria

Heckert, Eric, Karakoti, Ajay S., Seal, Sudipta, Self, William T.

01 June 2008

Cerium oxide nanoparticles (nanoceria) have recently been shown to protect cells against oxidative stress in both cell culture and animal models. Nanoceria has been shown to exhibit superoxide dismutase (SOD) activity using a ferricytochrome C assay, and this mimetic activity that has been postulated to be responsible for cellular protection by nanoceria. The nature of nanoceria's antioxidant properties, specifically what physical characteristics make nanoceria effective at scavenging superoxide anion, is poorly understood. In this study electron paramagnetic resonance (EPR) analysis confirms the reactivity of nanoceria as an SOD mimetic. X-ray photoelectron spectroscopy (XPS) and UV-visible analyses of nanoceria treated with hydrogen peroxide demonstrate that a decrease in the Ce 3+/4+ ratio correlates directly with a loss of SOD mimetic activity. These results strongly suggest that the surface oxidation state of nanoceria plays an integral role in the SOD mimetic activity of nanoceria and that ability of nanoceria to scavenge superoxide is directly related to cerium(III) concentrations at the surface of the particle.

cerium oxide

free radical

nanoparticle

superoxide

surface analysis

Role Ambiguity in the Face of Incongruent Demands: A Dynamic Role Theory Perspective

Bologna, Daniele A.

02 October 2018

No description available.

Management

Motivation

Engagement

Demands

Burnout

Exhaustion

Response Surface Analysis

Smart Surfaces in Biobased Materials

Becker, Ulrike

07 October 1998

The self-assembly blends of cellulose propionate (CP) and fluorine (F)-containing cellulose derivatives was examined on a model system of solvent cast films. The F-containing derivatives were either high molecular weight statistical cellulose esters with a number of F-containing substituent evenly distributed along the backbone (F-esters), or F-terminated CP-segments with exactly one F-containing endgroup. The F-esters were synthesized in a homogeneous phase and identified by 19F-NMR. Thermal analysis showed improved thermal stability of the F-esters when compared to F-free derivatives. 1-monohydroxy functionalized CP-segments were synthesized by HBr depolymerization using either a commercially available CP with residual OH-groups or a perpropionylated CP (CTP). The hydrolysis using the commercial CP yielded only segments of a minimum DP of 50 and the Mark-Houwink constant declined from 1 to 0.6. The results indicate that in the presence of free hydroxyls branches are formed by transglycosidation. The hydrolysis from perpropionylated CP resulted in segments with a minimum DP of 7, which is in accordance to previous studies. F-terminated CP segments were synthesized by coupling of the appropriate F-containing alcohol to the CP segment via toluene diisocyanate. Solutions containing F-terminated CP-segments showed typical critical micelle behavior. The critical micelle concentration depended on the molecular weight of the CP segment and the type of F-containing endgroup. The micelles are thought to consist of a core of the F-endgroups and a corona made-up of CP. Films containing the oligomers cast from micellar solution revealed a linear decrease in wetting force according to the blend composition of the oligomer, i.e. behavior according to the rule of mixing. This indicated the absence of surface segregation of the F-endgroup and it is explained with the fact that the micellar structure is retained in the solid state, suppressing surface segregation. The solid state micelles were visualized as dome-like protrusions by height image atomic force microscopy. In systems blended with CP the distance between the protrusions was found to increase with increasing CP content which was explained by a dilution process. Films containing F-esters were characterized by wetting force measurements and x-ray photoelectron spectroscopy (XPS). The wetting force decreased dramatically at low blend content of the F-ester and at the same time an F surface-concentration higher then expected from the blend composition was found by XPS. This indicated self-assembly by surface segregation of the F-containing species during film formation. The extent of surface segregation was found to depend on the type of the F-ester group as well as on the blend concentration of the F-ester. Dynamic wetting force measurements revealed hysteresis in films containing either F-esters or F-terminated CP segments. The hysteresis was found to be both kinetic (water sorption and reorganization) and thermodynamic (surface roughness and surface coverage with F-moieties) in nature. Consecutive force loops revealed an increase in the wetting force (advancing and receding) with increasing loop number, indicating the increased hydrophobicity of the surface. The force increase was determined to be due to water sorption as well as due to surface reorganization. An increase in the size of the F-groups signified a decrease in reorganization rate due to a decreased mobility of the group. The process of reorganization was fully reversible, a behavior which is congruent with the definition of smart behavior. / Ph. D.

cellulose propionate

surface analysis

surface segregation

reorganization

XPS

AFM

Experimental studies of materials migration in magnetic confinement fusion devices : Novel methods for measurement of macro particle migration, transport of atomic impurities and characterization of exposed surfaces

Bykov, Igor

January 2014

During several decades of research and development in the field of Magnetically Confined Fusion (MCF) the preferred selection of materials for Plasma Facing Components (PFC) has changed repeatedly. Without doubt, endurance of the first wall will decide research availability and lifespan of the first International Thermonuclear Research Reactor (ITER). Materials erosion, redeposition and mixing in the reactor are the critical processes responsible for modification of materials properties under plasma impact. This thesis presents several diagnostic techniques and their applications for studies of materials transport in fusion devices. The measurements were made at the EXTRAP T2R Reversed Field Pinch operated in Alfvén laboratory at KTH (Sweden), the TEXTOR tokamak, recently shut down at Forschungszentrum Jülich (Germany) and in the JET tokamak at CCFE (UK). The main outcomes of the work are: Development and application of a method for non-destructive capture and characterization of fast dust particles moving in the edge plasma of fusion devices, as well as particles generated upon laser-assisted cleaning of plasma exposed surfaces.  Advancement of conventional broad beam and micro ion beam techniques to include measurement of tritium in the surfaces exposed in future D-T experiments.  Adaption of the micro ion beam method for precision mapping of non uniform elements concentrations on irregular surfaces.  Implementation of an isotopic marker to study the large scale materials migration in a tokamak and development of a method for fast non destructive sampling of the marker on surfaces of PFCs. / <p>QC 20140508</p>

fusion

tokamak

RFP

divertor

limiter

SOL

transport

migration

surface analysis

IBA

ion micro beam

beryllium

tritium