Molecular thin films and their role in controlling interface properties

Iarikov, Dmitri

15 October 2013

In the first part of this study, frictional and normal forces in aqueous solutions were measured between a glass particle and oligopeptide films grafted from a glass plate. Homopeptide molecules consisting of 11 monomers of different amino acids were each "grafted from" an oxidized silicon wafer using microwave-assisted solid phase peptide synthesis. Oligopeptides increased the magnitude of friction compared to a bare hydrophilic silicon wafer. Friction was a strong function of the nature of the monomer unit and was lower for hydrophilic films. There was a strong adhesion and therefore friction between surfaces of opposite charges. Changes in adhesion and friction depended on the hydrophobicity and electrostatic forces: hydrophobic films and oppositely charged films produced high friction, whereas hydrophilic and like-charges produced low friction. Friction was lower in phosphate buffered saline than in pure water due to the screening of the double layer attraction for oppositely charged surfaces and additional lubrication by hydrated salt ions. We also investigated antimicrobial action of poly (allyl amine) (PA) when covalently bonded to glass. Glass surfaces were prepared by a two-step procedure where the glass was first functionalized with epoxide groups using 3-glycidoxypropyltrimethoxy silane (GOPTS) and then exposed to PA to bind via reaction of a fraction of its amine groups. Antibacterial properties of these coatings were evaluated by spraying aqueous suspensions of bacteria on the functionalized glass slides, incubating them under agar, and counting the number of surviving cell colonies. The PA film displayed strong anti-microbial activity against both Gram-positive and Gram-negative bacteria. Films that were prepared by allowing the PA to self assemble onto the solid via electrostatic interactions were ineffective antimicrobials. Such films had an insufficient positive charge and did not extend far from the solid. Thus we found that antimicrobial activity was correlated with a combination of the ability of the polymer chain to extend into solution and a positive surface potential. / Ph. D.

antimicrobial surfaces

poly(allylamine)

lateral force microscopy

atomic force microscopy

peptide synthesis

The Correlated Dynamics of Micron-Scale Cantilevers in a Viscous Fluid

Robbins, Brian A.

08 December 2014

A number of microcantilever systems of fundamental importance are explored using theoretical and numerical methods to quantify and provide physical insights into the dynamics of experimentally accessible systems that include a variety of configurations and viscous fluids. It is first shown that the correlated dynamics of both a laterally and vertically offset cantilever pair can be accurately predicted by numerical simulations. This is verified by comparing the correlated dynamics yielded by numerical simulations with experimental measurement. It is also demonstrated that in order to obtain these accurate predictions, geometric details of the cantilever must be included in the numerical simulation to directly reflect the experimental cantilever. A microrheology technique that utilizes the fluctuation-dissipation theorem is proposed. It is shown that by including the frequency dependence of the fluid damping, improvements in accuracy of the predictions of the rheological properties of the surrounding fluid are observed over current techniques. The amplitude spectrum of a 2-D cantilever in a power-law fluid is studied. The resulting amplitude spectrum yielded a curve similar to an overdamped system. It is observed that the amplitude and noise spectrum yield the same qualitative response for a 2-D cantilever in a shear thinning, power-law fluid. The correlated dynamics of a tethered vertically offset cantilever pair is investigated. It is shown that for a range of stiffness ratios, which is the ratio of the spring constant of the tethering relative to the cantilever spring constant, the change in the correlated dynamics of a Hookean spring tethered cantilever pair can be seen in the presence of fluid coupling. The dynamics of a spring-mass tethered, vertically offset cantilever pair is qualitatively studied by simplifying the model to an array of springs and masses. The resulting study found that the correlated dynamics of the displacement of mass of the tethered object yielded newly observed features and characteristics. It is shown that the curve shape of the cross-correlation of the displacement of the mass of the tethered object is similar to that of the auto-correlation of the displacement of the mass representing a step forced cantilever. The cross-correlation of the displacement of the mass of the tethered object, however, is found to be significantly more dependent on the stiffness ratio than the auto-correlation of the displacement of the mass representing a cantilever for t > 0. At t = 0, it is observed that the mass of the tethered object yields the same finite value for the cross-correlation for all studied values of the stiffness ratio. This characteristic is a result of the symmetry of the studied spring-mass system. / Ph. D.

fluid dynamics

fluctuation-dissipation theorem

correlation force spectroscopy

atomic force microscopy

microrheology

single-molecule dynamics

Controlling Colloidal Stability using Highly Charged Nanoparticles

Herman, David J.

27 February 2015

This dissertation focused on the potential use of highly charged nanoparticles to stabilize dispersions of weakly charged microparticles. The experimental components of the project centered on a model colloidal system containing silica microparticles at the isoelectric point where the suspensions are unstable and prone to flocculation. The stability of the silica suspensions was studied in the presence of highly charged nanoparticles. Initial experiments used polystyrene latex with either sulfate or amidine surface groups. Effective zeta potentials were measured with nanoparticle concentrations ranging from 0.001% to 0.5% vol. Adsorption levels were determined through direct SEM imaging of the silica microparticles, showing that the nanoparticles directly adsorbed to the microparticles (amidine more than sulfate), producing relatively large effective zeta potentials. However, stability experiments showed that the latex nanoparticles did not stabilize the silica but merely provided a reduction in overall flocculation rate. It was concluded that the zeta potential was an insufficient predictor of stability as there was still sufficient patchiness on the surface to allow for the silica surfaces to aggregate. Experiments using zirconia and alumina nanoparticles did achieve effective stabilization; both types stabilized the silica suspensions for longer than the observation period of approximately 15 hours. Stability was observed at concentrations of 10^-4% to 1.0% (zirconia) and 10^-2% vol. (alumina). These particles adsorbed directly to the microparticles (confirmed via SEM) and produced increasing effective zeta potentials with increasing nanoparticle concentrations. The adsorption resulted in significant electrostatic repulsion that was determined to be effectively irreversible using colloidal probe AFM. The improved stabilizing ability was attributed to the increased van der Waals attraction between the oxide nanoparticles (compared to polystyrene). Finally, an unexpected result of the CP-AFM force measurements showed that the repulsive forces between a nanoparticle-coated particle and plate lacked the normal dependence on the radius of the probe as predicted by the Derjaguin approximation. The forces observed in nanoparticle suspensions were virtually identical for 5 µm and 30 µm probes. Based on calculations of the shear rate in the gap, it was theorized that this phenomenon may have resulted from the shearing of adsorbed particles from the surfaces, which leads to similar interaction geometries for the two probe sizes. / Ph. D.

Colloidal stability

nanoparticle adsorption

electrostatic forces

van der Waals interactions

atomic force microscopy

Controlled Evaluation of Silver Nanoparticle Dissolution: Surface Coating, Size and Temperature Effects

Liu, Chang

30 March 2020

The environmental fate and transport of engineered nanomaterials have been broadly investigated and evaluated in many published studies. Silver nanoparticles (AgNPs) represent one of the most widely manufactured nanomaterials. They are currently being incorporated into a wide range of consumer products due to their purported antimicrobial properties. However, either the AgNPs themselves or dissolved Ag+ ions has a significant potential for the environmental release. The safety issues for nanoparticles are continuously being tested because of their potential danger to the environment and human health. Studies have explored the toxicity of AgNPs to a variety of organisms and have shown such toxicity is primarily driven by Ag+ ion release. Dissolution of nanoparticles is an important process that alters their properties and is a critical step in determining their safety. Therefore, studying nanoparticles' dissolution can help in the current move towards safer design and application of nanoparticles. This research endeavor sought to acquire comprehensive kinetic data of AgNP dissolution to aid in the development of quantitative risk assessments of AgNP fate. To evaluate the dissolution process in the absence of nanoparticle aggregation, AgNP arrays were produced on glass substrates using nanosphere lithography (NSL). Changes in the size and shape of the prepared AgNP arrays were monitored during the dissolution process by atomic force microscopy (AFM). The dissolution of AgNP is affected by both internal and external factors. First, surface coating effects were investigated by using three different coating agents (BSA, PEG1000, and PEG5000). Capping agent effects nanoparticle transformation rate by blocking reactants from the nanoparticle surface. Coatings prevented dissolution to different extents due to the various way they were attached to the AgNP surface. Evidence for the existence of bonds between the coating agents and the AgNPs was obtained by surface enhanced Raman spectroscopy. Moreover, to study the size effects on AgNP dissolution, small, medium, and large sized AgNPs were used. The surrounding medium and temperature were the two variables that were included in the size effects study. Relationships were established between medium concentration and dissolution rate for three different sized AgNP samples. By using the Arrhenius equation to plot the reaction constant vs. reaction temperature, the activation energy of AgNPs of different sizes were obtained and compared. / Doctor of Philosophy / Nanomaterials, defined as materials with at least one characteristic dimension less than 100 nm, often have useful attributes that are distinct from the bulk material. The novel physical, chemical, and biological properties enable the promising applications in various manufacturing industry. Silver nanoparticles (AgNPs) represent one of the most widely manufactured nanomaterials and has been used as the antimicrobial agent in a wide range of consumer products. However, either the AgNPs themselves or dissolved Ag+ ions has a significant potential for the environmental release. The environmental fate and transport of AgNPs drawn considerable attentions because of the potential danger to environment and human health. Dissolution of nanoparticles is an important process that alters their properties and is a critical step in determining their safety. Ag+ ions migrate from the nanoparticle surface to the bulk solution when an AgNP dissolves. Studying nanoparticles' dissolution can help in the current move towards safer design and application of nanoparticles. This research aimed to acquire comprehensive kinetic data of AgNP dissolution to aid in the development of quantitative risk assessments of AgNP fate. AgNP arrays were produced on glass substrates using nanosphere lithography (NSL) and changes in the size and shape during the dissolution process were monitored by atomic force microscopy (AFM). First, surface coating effects were investigated by using three different coating agents. Coatings prevented dissolution to different extents due to the various way they were attached to the AgNP surface. Moreover, small, medium, and large sized AgNPs were used to study the size effects on AgNP dissolution. The surrounding medium concentration and temperature were the two variables that were included in the size effects study.

Nanotechnology

silver nanoparticles

nanosphere lithography

dissolution

atomic force microscopy

surface functionalization

size effects

temperature effects

Integrated Experimental Characterization of the Lower Huron Shale in the Central Appalachian Basin

Tan, Xinyu

04 June 2020

Reservoir characterization is an essential step in the oil/gas exploration process and is of great significance in the evaluation of oil/gas resources. To evaluate the production potential of the Lower Huron shale in the central Appalachian Basin, matrix permeability, Raman spectroscopy, Fourier Transform infrared spectroscopy (FTIR), and atomic force microscopy (AFM) were used in this study. According to the experimental results, matrix permeability is relatively high for a shale gas formation, suggesting great production potential of shale gas resources in this region. Additionally, four shale samples with varying thermal maturity were characterized by the complementary Raman and FTIR spectroscopy, and curve-fitting results successfully demonstrated the change of chemical structures with the evolution of thermal maturity. Raman spectroscopy results show that the curve fitted G band position and the band separation between the G band and D1 band tend to increase with the rise of thermal maturity level. Results of FTIR spectroscopy show that the aromaticity level and the condensation extent of aromatic rings show an increasing tendency with the increase of maturation level. Moreover, mechanical properties of these four shale samples were characterized by AFM. Results show that Young's modulus is in the range of 8.20 GPa - 12.94 GPa, which is in the normal range compared with the results from other shale formations. Additionally, scanned results show an increasing tendency for Young's modulus of the organic components with the rise of thermal maturity level in these shale samples. The potential reason for this phenomenon was also explored, specifically, the growth of aromatic groups and the decrease of the CH2/CH3 ratio may be possible reasons for the rise of Young's modulus of organic components in these shale samples. This work is meaningful for the evaluation of shale gas resources, especially emerging plays, in the central Appalachian Basin, and it also provides a valuable database for relevant research on shale matrix permeability, Raman, FTIR and AFM. / Master of Science / Reservoir characterization is important in evaluating the production potential of unconventional resources. The purpose of this work is to characterize key reservoir properties of shale samples from the central Appalachian Basin to provide support for improved shale gas production in this region. This work includes the analysis of matrix permeability testing, Raman and Fourier Transform infrared spectroscopy (FTIR) characterization, and atomic force microscopy (AFM) mapping. Matrix permeability testing results show that the matrix permeability of these six samples is relatively high for a shale gas formation, suggesting great production potential of shale gas resources in this region. Additionally, four shale samples with different thermal maturity were scanned using Raman and FTIR spectroscopy, and mineral components of these same four samples were also identified by the FTIR analysis. Processed Raman data show that two important measures, the G band position and the difference between the G band position and D1 band position, tend to increase with the rise of thermal maturity. FTIR results show that the aromaticity rings would likely be compressed due to the increased number of aromaticity rings. Also, AFM provides a high-resolution map for the Young's modulus, a measure of material stiffness, of these four samples. The modulus value is in the normal range compared with scans from other shale formations. In addition, the modulus value tends to increase with the increase of thermal maturity level. The increase of aromatic rings and the decrease of the CH2/CH3 ratio can be regarded as potential reasons for the change of modulus value. This work has potential to improve the production design of shale gas resources, especially emerging plays, in the central Appalachian Basin and can be regarded as a valuable reference for other similar research.

Reservoir characterization

matrix permeability

Raman and FTIR spectroscopy

atomic force microscopy (AFM)

Dynamic mechanical analysis of collagen fibrils at the nanoscale.

Grant, Colin A., Phillips, M.A., Thompson, N.H.

05 September 2011

No / Low frequency (0.1¿2 Hz) dynamic mechanical analysis on individual type I collagen fibrils has been carried out using atomic force microscopy (AFM). Both the elastic (static) and viscous (dynamic) responses are correlated to the characteristic axial banding, gap and overlap regions. The elastic modulus (¿5 GPa) on the overlap region, where the density of tropocollagen is highest, is 160% that of the gap region. The amount of dissipation on each region is frequency dependent, with the gap region dissipating most energy at the lowest frequencies (0.1 Hz) and crossing over with the overlap region at ¿0.75 Hz. This may reflect an ability of collagen fibrils to absorb energy over a range of frequencies using more than one mechanism, which is suggested as an evolutionary driver for the mechanical role of type I collagen in connective tissues and organs. / BBSRC

Dynamic mechanical analysis

Elastic modulus

Collagen fibrils

Atomic force microscopy (AFM).

Nano-Scale Observations of Tattoo Pigments in Skin by Atomic Force Microscopy

Grant, Colin A., Twigg, Peter C., Tobin, Desmond J.

26 March 2015

No / In this study, we have shown how particles in carbon black tattoo ink accumulate in the human skin dermis using fine-resolution atomic force microscopy, with which a single ink particle in the collagenous network can be imaged. This information further demonstrates that tattoo inks are nano-particles. Further, we have deposited a commercially available tattoo ink on a glass slide and calculated a range of volumes for single ink particles.

Tattoo pigments

Carbon black tattoo ink

Human skin

Atomic force microscopy

Vers la réalisation de composants nanoélectroniques par anodisation localisée par AFM / Toward the realization of metalic nanoelectronic devices using local anodisation by AFM

Guillaume, Nicolas

14 December 2015

Ce travail de thèse se compose de deux parties : tout d’abord nous avons caractérisé sur le plan morphologique des motifs de TiOx réalisés par anodisation localisée par AFM (LAO) dans des couches pleines plaques de 5 nm de titane. Nous avons étudié l’influence de la tension d’oxydation, de la vitesse de balayage de la pointe AFM, de l’humidité relative de l’environnement, du mode AFM (contact ou intermittent) et du type de pointe. Les motifs les plus fins atteignent une largeur à mi-hauteur de 21 nm pour 2.2 nm de hauteur, ils sont obtenus avec une pointe PtSi utilisée en mode intermittent sous une tension de polarisation de -7V, une vitesse de balayage de 0.4 µm.s-1 et dans un environnement comportant une humidité de 43%. La deuxième partie de notre travail a été consacrée à l’élaboration et à la caractérisation de jonctions planaires MIM Ti/TiOx/Ti. Ces jonctions sont des motifs TLM de titane comportant une ligne transverse de TiOx réalisée par LAO. Lorsque les jonctions sont stressées électriquement sous air, une transformation morphologique irréversible se produit pour une densité de courant et un champ électrique atteignant de l’ordre de 7.1010 A.m-2 et 3.107 V.m-1 respectivement. Des analyses chimiques et structurales basées sur la microscopie électronique à transmission ont montré que la ligne initiale de TiOx amorphe s’était considérablement élargie et est constituée d’une zone de TiOx cristallin. Cette transformation peut être évitée en appliquant le stress électrique sous vide. Enfin des mesures électriques en température ont permis d’élucider les mécanismes de conduction : émission Schottky sous vide et conduction ionique sous air. / This work is divided in two specific parts: first of all we caracterized oxide patterns made by local anodic oxidation using an AFM on 5nm titanium wafers. We caracterized the morphology of the patterns. We studied the influence of several parameters such as oxidation voltage, writing speed of the AFM tip, relative humidity of the environment, AFM modes (contact or tapping)and the type of the tips we used. Most thinnest pattern we made reaches a full width at half maximum of 21nm with a 2.2nm height. It was obtained using a PtSi coating tip in tapping mode with an oxidation voltage of -7V, a writing speed of 0.4 um/s and a relative humidity of 43%. The second part of our work was dedicated to the realization and the characterization of planar MIM junction Ti/TiOx/Ti. These junctions are TLM patterns with a TiOx line cross-ways over the microwire of the TLM pattern. When the junctions are stressed electrically under ambient atmosphere, an irreversible morphological transformation is happenning for a current density and an electric field of 7.1010 A/m² and 3.107 V/m respectively. Chemical and structural analysis based on transmission electronic microscopy have shown that the initial amorphous TiOx junction have grown importantly with an area of crystalline TiOx. This transformation can be avoided by applying the electric stress under vacuum. Finally, electrical measurements in temperature highlighted the transport mecanisms within the junction: Schottky emission under vacuum and ionic conduction under ambient atmosphere.

Electronique

Nanoélectronique

Anodisation métallique

AFM - Atomic force microscopy

Couches minces

Résistivité électrique

Transport

Titane

Conduction ionique

Electronics

Nanoelectronics

Metal anodization

AFM - Atomic force microscopy

Titanium

Thin films

Resistivity

621.381 620 107 2

Interfacial and Mechanical Properties of Carbon Nanotubes: A Force Spectroscopy Study

Poggi, Mark Andrew

22 September 2004

Next generation polymer composites that utilize the high electrical conductivity and tensile strength of carbon nanotubes are of interest. To effectively disperse carbon nanotubes into polymers, a more fundamental understanding of the polymer/nanotube interface is needed. This requires the development of new analytical methods and techniques for measuring the adhesion between a single molecule and the sidewalls of carbon nanotubes. Atomic Force Microscopy is an integral tool in the characterization of materials on the nanoscale. The objectives of this research were to: 1) characterize the binding force between single molecules and the backbone of a single walled carbon nanotube (SWNT), and 2) measure and interpret the mechanical response of carbon-based nano-objects to compressive loads using an atomic force microscope. To identify chemical moieties that bind strongly to the sidewall of the nanotubes, two experimental approaches have been explored. In the first, force volume images of SWNT paper were obtained using gold-coated AFM tips functionalized with terminally substituted alkanethiols and para-substituted arylthiols. Analysis of these images enabled quantification of the adhesive interactions between the functionalized tip and the SWNT surface. The resultant adhesive forces were shown to be dependent upon surface topography, tip shape, and the terminal group on the alkanethiol. The mechanical response of several single- and multi-walled carbon nanotubes under compressive load was examined with an AFM. When the scanner, onto which the substrate has been mounted, was extended and retracted in a cyclic fashion, cantilever deflection, oscillation amplitude and resonant frequency were simultaneously monitored. By time-correlating cantilever resonance spectra, deflection and scanner motion, precise control over the length of nanotube in contact with the substrate, analogous to fly-fishing was achieved. This multi-parameter force spectroscopy method is applicable for testing the mechanical and interfacial properties of a wide range of nanoscale objects. This research has led to a clearer understanding of the chemistry at the nanotube/polymer interface, as well as the mechanical response of nanoscale materials. A new force spectroscopic tool, multi-parameter force spectroscopy, should be extremely helpful in characterizing the mechanical response of a myriad of nanoscale objects and enable nanoscale devices to become a reality.

Composites

Nanotube composites

Single wall carbon nanotubes

Multiwall carbon nanotubes

MPFS

Multi-parameter force spectroscopy

Force spectroscopy

Atomic force microscopy

Carbon nanotubes

Spectrum analysis

Atomic force microscopy

Carbon Mechanical properties

Nanotubes Mechanical properties

Polymeric composites

Atomic force microscopy study on the mechanics of influenza viruses and liposomes / Rasterkraftmikroskop Studie der Mechanik von Influenza-Viren und Liposomen

Li, Sai

20 November 2012

Physik gibt es überall dort, wo Materie: Maßnahmen wie Energie, Masse, Temperatur, Geschwindigkeit, Größe und Steifigkeit sind alle Beispiele der physikalischen Eigenschaften. Solche Mengen sind wichtige Charakterisierungen für biologische Organismen: Sie verändern die ganze Zeit während des gesamten Lebenszyklus. Für eine Bio-Mechaniker, Steifigkeit ist eine wichtige Maßnahme zur biologischen Design zu verstehen. Weil biologische Bausteine so klein wie 1 nm (Protein / DNA / Lipid) sein können, sind spezielle Techniken erforderlich, um ihre Steifigkeit zu studieren. Beide Rasterkraftmikroskopie (AFM) und optischen Pinzetten können verwendet werden, um aktiv zu verformen die Objekte an pN-nN Kräfte und messen die Verformung auf Nanometer Längenskalen werden. In dieser Arbeit AFM wird angewandt, um die Mechanik von Influenza-Viren, Liposomen und lebenden Zellen zu studieren. Das Genom von Viren von einer Proteinhülle und in einigen Fällen eine zusätzliche Lipidhülle verpackt. Dieser Verbund Shell hat widersprüchliche Rollen: er hat das virale Genom zu schützen, aber es sollte auch ermöglichen Auspacken während der viralen Infektion in das Genom zu lösen. Influenza-Virus ist das weichste Virus jemals gefunden, aber zur gleichen Zeit eine sehr hartnäckige Virus verursacht jährliche Pandemien. Ein besseres Verständnis der mechanischen Eigenschaften des Influenza-Virus kann uns helfen zu verstehen, warum das Virus so erfolgreich ist. Die mechanischen Eigenschaften von Influenza-Viren wurden durch AFM gemessen und mit den Liposomen der viralen Lipid hergestellt. Wir haben gefunden, dass die Influenzavirus-Mechanik durch seine Lipidhülle (~ 70%) werden dominiert. In Kapitel 2 haben wir gezeigt, dass anstelle der Verwendung einer starren Proteinkapsid die Lipidhülle ausreicht, um das Influenza virale Genom zu schützen. In Kapitel 3 haben wir weitere blickte in die Funktion des M1 Proteinhülle während der viralen Infektion. Ein Zwischenprodukt Auspacken Schritt wurde durch Messen der in fluenzavirale Steifigkeit bei pH 7, 6, 5,5 und 5, Bedingungen, die die Ansäuerung Umgebungen auf der viralen Infektion nachahmen Stoffwechselweg entdeckt. Der Zwischenschritt wurde weiterhin als wesentlich erwiesen für eine erfolgreiche Infektion. Wir schlagen vor, dass das Influenza-Virus hat sich zu eng synchronisiert die verschiedenen Schritte ihrer Auspacken mit pH-

570 Biowissenschaften

Biologie

WCP 000

Physics

Influenza-Virus

Liposomen

Biomechanik

atomic force microscopy

Finite Elemente Methode

Endozytose

M1 Matrixprotein

umhüllte Virus

Influenza virus

liposome

biomechanics

atomic force microscopy

finite element method

endocytosis

M1 matrix protein

enveloped virus

42