Study of Mechanical Properties of PVA Fiber-Reinforced Concrete With Raman Spectroscopic Analysis

Annam, Ramyasree

01 May 2015

The brittleness of concrete has always been a safety and economic issue of great concern. The low tensile strength of concrete is the cause of its intrinsic brittle nature. This is critical considering the amount of concrete used for the construction of highways, buildings, and other facilities. The mechanical properties of concrete must be improved to provide upgraded construction. Crack resistant and durable concrete has always been a major goal for engineers. Many approaches have been tried to make concrete a better construction material. Fiber reinforcement is an approach which has been shown to improve the quality and durability of concrete. The focus of this research is to develop a mix design of fiber reinforced concrete and then test these materials for both compressive and tensile strength after casting into cubes. The effect of polyvinyl alcohol fibers on the mechanical properties of concrete was also studied. The impacts of moisture and the stress applied on the fibers were determined using Raman spectroscopy.

compressive strength

tensile strength

Raman Spectroscopy

Inorganic Chemistry

Materials Chemistry

Polymer Chemistry

Raman Spectroscopy and Hyperspectral Analysis of Living Cells Exposed to Nanoparticles

Ahlinder, Linnea

January 2015

Nanoparticles, i.e. particles with at least one dimension smaller than 100 nm, are present in large quantities in ambient air and can also be found in an increasing amount of consumer products. It is known that many nanomaterials have physicochemical properties that differ from physicochemical properties of the same material in bulk size. It is therefore important to characterize nanoparticles and to evaluate their toxicity. To understand mechanisms behind nanotoxicity, it is important to study the uptake of nanoparticles, and how they are accumulated. For these purposes model studies of cellular uptake are useful. In this thesis metal oxide and carbon-based nanoparticles have been studied in living cells using Raman spectroscopy. Raman spectroscopy is a method that facilitates a non-destructive analysis without using any fluorescent labels, or any other specific sample preparation. It is possible to collect Raman images, i.e. images where each pixel corresponds to a Raman spectrum, and to use the spectral information to detect nanoparticles, and to identify organelles in cells. In this thesis the question whether or not nanoparticles can enter the cell nucleus of lung epithelial cells has been addressed using hyperspectral analysis. It is shown that titanium dioxide nanoparticles and iron oxide nanoparticles are taken up by cells, and also in the cell nucleus. In contrast, graphene oxide nanoparticles are mainly found attached on the outside of the cell membrane and very few nanoparticles are found in the cell, and none have been detected in the nucleus. It is concluded that graphene oxide nanoparticles are not cytotoxic. However, a comparison of Raman spectra of biomolecules in cells exposed to graphene oxide, unexposed cells and apoptotic cells, shows that the graphene oxide nanoparticles do affect lipid and protein structures. In this thesis, several multivariate data analysis methods have been used to analyze Raman spectra and Raman images. In addition, super-resolution algorithms, which originally have been developed to improve the resolution in photographic images, were optimized and applied to Raman images of cells exposed to submicron polystyrene particles in living cells.

Raman spectroscopy

Hyperspectral analysis

Multivariate data analysis

Nanotoxicology

Graphene oxide

Iron oxide

Titanium dioxide

Cells

Raman modes in index-identified individual single-walled and multi-walled carbon nanotubes

Levshov, Dmitry

16 December 2013

The main objective of this work is the fundamental physical study of individual isolated carbon nanostructures in order to address their intrinsic vibrational and optical properties and also to estimate and quantify the environmental effects. For these purposes, we synthesized individual single- and multi-walled carbon nanotubes by chemical vapour deposition method on dedicated substrates. The main aspect of the work involves the combined use of different experimental probes on the same individual nanostructures. We performed a complete structure analysis by electron diffraction and high-resolution electron microscopy and the measurement of the Raman spectra on these individual nanostructures. Several important environmental effects were evidenced for the first time, e.g. the effect of mechanical coupling (van-der-Waals interaction) between the layers of double-walled carbon nanotubes leading to the change in the low-frequency Raman modes and the optical resonance conditions. Moreover the behaviour of high-frequency modes of double-walled tubes was also analysed and described. As a result of this work several experimental criteria for structure diagnostics of multi-walled carbon nanotubes were proposed.

Raman spectroscopy

Carbon nanotube

Electron diffraction

Applications for the Electroless Deposition of Gold Nanoparticles onto Silicon

Millard, Morgan

12 July 2013

Gold nanoparticles were deposited onto a silicon substrate using electroless deposition. The process was optimized by adjusting the deposition time, the temperature of the plating solution, the amount of time that the silicon was exposed to hydrofluoric acid, and the concentration of the plating solution. The nanoparticles deposited on the silicon were characterized using scanning electron microscopy. The optimized electroless deposition process was then used to modify the surface of silicon solar cells with gold nanoparticles for enhanced power generation. Spectral response and I-V curve tests were performed on the modified solar cells to quantify the enhancements. The modified surfaces of the silicon solar cells were characterized by scanning electron microscopy and reflectance measurements. The electroless deposition process was also used to generate nanostructures for surface-enhanced Raman scattering (SERS). A template-nanohole array was fabricated on silicon by focused ion beam milling. Gold nanoparticles were deposited in the holes of the template, resulting in interesting gold-nanodoughnut structures. The gold nanodoughnuts were examined by scanning electron microscopy, and their potential as SERS substrates were tested using Rhodamine 6G as a molecular probe under 633 nm laser excitation. / Graduate / 0494 / 0485 / mmillard@uvic.ca

electoless deposition

silicon solar cells

surface enhanced raman spectroscopy

gold nanostructures

Development of a Raman microscope for applications in radiobiology

Matthews, Quinn

23 July 2008

Raman microscopy (RM) is a vibrational spectroscopic technique capable of obtaining sensitive measurements of molecular composition, structure, and dynamics from a very small sample volume (~1 µm). In this work, a RM system was developed for future applications in cellular radiobiology, the study of the effects of ionizing radiation on cells and tissues, with particular emphasis on the capability to investigate the internal molecular composition of single cells (10-50 µm in diameter). The performance of the RM system was evaluated by imaging 5 µm diameter polystyrene microbeads dispersed on a silicon substrate. This analysis has shown that RM of single cells is optimized for this system when using a 100x microscope objective and a 50 µm confocal collection aperture. Quantitative measurements of the spatial, confocal, and spectral resolution of the RM system have been obtained using metal nanostructures deposited on a flat silicon substrate. Furthermore, a spectral investigation of several substrate materials was successful in identifying low-fluorescence quartz as a suitable substrate for RM analysis of single cells. Protocols have been developed for culturing and preparing two human tumor cell lines, A549 (lung) and DU145 (prostate), for RM analysis, and a spectroscopic study of these two cell lines was performed. Spectra obtained from within cell nuclei yielded detectable Raman signatures from all four types of biomolecules found in a human cell: proteins, lipids, carbohydrates, and nucleic acids. Furthermore, Raman profiles and 2D maps of protein and DNA distributions within single cells have been obtained with micron-scale spatial resolution. It was also found that the intensity of Raman scattering is highly dependent on the concentration of dense nuclear material at the point of Raman collection. RM shows promise for studying the interactions of ionizing radiation with single cells, and this work has been successful in providing a foundation for the development of future radiobiological RM experiments.

Medical Physics

Radiobiology

Raman spectroscopy

Raman microscope

Applications for the Electroless Deposition of Gold Nanoparticles onto Silicon

Millard, Morgan

12 July 2013

Gold nanoparticles were deposited onto a silicon substrate using electroless deposition. The process was optimized by adjusting the deposition time, the temperature of the plating solution, the amount of time that the silicon was exposed to hydrofluoric acid, and the concentration of the plating solution. The nanoparticles deposited on the silicon were characterized using scanning electron microscopy. The optimized electroless deposition process was then used to modify the surface of silicon solar cells with gold nanoparticles for enhanced power generation. Spectral response and I-V curve tests were performed on the modified solar cells to quantify the enhancements. The modified surfaces of the silicon solar cells were characterized by scanning electron microscopy and reflectance measurements. The electroless deposition process was also used to generate nanostructures for surface-enhanced Raman scattering (SERS). A template-nanohole array was fabricated on silicon by focused ion beam milling. Gold nanoparticles were deposited in the holes of the template, resulting in interesting gold-nanodoughnut structures. The gold nanodoughnuts were examined by scanning electron microscopy, and their potential as SERS substrates were tested using Rhodamine 6G as a molecular probe under 633 nm laser excitation. / Graduate / 0494 / 0485 / mmillard@uvic.ca

electoless deposition

silicon solar cells

surface enhanced raman spectroscopy

gold nanostructures

X-ray and light scattering from nanostructured thin films

Bassi, Andrea Li

January 2000

The object of this thesis is the study of nanostructured thin films using inelastic fight scattering and elastic x-ray scattering techniques. Their use in combination with other techniques is a powerful tool for the investigation of nanostructured materials. X-ray, Raman and Brillouin characterisation of cluster-assembled carbon films, promising for applications in the field of catalysis, hydrogen storage and field emission, is here presented. X-ray reflectivity (XRR) provided a measure of the density. Raman spectroscopy showed that the local bonding in these amorphous films depends on the size distribution of the clusters and that it is possible to select the cluster size in order to grow films with tailored properties. Brillouin scattering provided a characterisation at the mesoscopic scale and an estimate of the elastic constants, revealing a very soft material. XRR was employed to study density, layering and roughness of a wide range of amorphous carbon films grown with different techniques. Some films possess an internal layering due to plasma instabilities in the deposition apparatus. By comparing XRR with Electron Energy Loss Spectroscopy, a unique value for the electron "effective mass" was deduced and a general relationship between sp(^3)-content and density was found. XRR and H effusion were used to determine the hydrogen content. A study of the size-dependent melting temperature in tin nanoparticle thin films was undertaken with a combined use of X-Ray Diffraction (XRD) and light scattering. A redshift in the position of a Rayleigh peak in the temperature-dependent Brillouin measurements was shown to be related to the melting of the nanoparticles and explained by an effective medium model. XRD also provided information on the low-level of stress in the particles. Low-frequency Raman scattering was used to study the behaviour of the acoustic modes of a single particle as a function of temperature.

530.41

Raman and near infrared spectroscopic analysis of amniotic fluid : metabolomics of maternal and fetal health indicators

Power, Kristin Marie.

January 2007

This thesis presents quantitative tools for the metabolomic analysis of amniotic fluid (AF) using vibrational spectroscopy. A total of 300 AF samples were collected for this retrospective cohort study and both Raman and near infrared (NIR) spectra were measured. Spectral data was compressed using a Haar wavelet transform and stage-wise multilinear regression (MLR). Calibration models were calculated for glucose, lactate and uric acid concentrations in AF. Birth weight, gestational diabetes mellitus (GDM) and gestational age were classified with the resulting compressed Raman and NIR spectra, using a genetic algorithm (GA) and a cross-validation approach. Results show that both Raman and NIR spectra of AF were not able to estimate the concentrations of glucose, lactate or uric acid with high precision. However, metabolomic analysis of AF Raman and NIR spectra was capable of estimating the development of GDM, abnormal birth weights as well as gestational ages with sensitivities >75% and specificities >77%. In addition, Raman and NIR metabolomic profiles showed a statistical difference in patients delivering preterm. Of the two spectroscopic analyses studied, NIR spectroscopy of AF has the potential to become a robust and non-invasive diagnostic tool for maternal and fetal health.

Amniotic liquid -- Analysis.

Raman spectroscopy.

Near infrared spectroscopy.

Fetus -- Growth.

Birth weight.

Diabetes in pregnancy.

Development of a Surface Enhanced Raman Spectroscopy Platform Technology to Detect Cardiac Biomarkers of Myocardial Infarction

Benford, Melodie Elane

03 October 2013

The clinical evaluation of people with possible myocardial infarction (MI) is often limited by atypical symptoms and inconclusive initial electrocardiograms. A recent consensus from the American College of Cardiology has redefined acute MI to include cardiac markers as central to diagnosis. To address this clinical need, a sensitive microfluidic surface-enhanced Raman spectroscopy (SERS) nanochannel-based optical device is being developed for ultimate use as a point-of-care device for the simultaneous measurement of MI blood biomarkers. The device can provide enhancements of the Raman signal of the analyte measured of up to 1013 using a mechanical aggregation technique at the interface of nanofluidic structures enabling repeatable SERS measurements. Specifically in this research iterations of a sensitive, low volume SERS platform technology were designed that provided quantitative information across a specific range. With the SERS platforms studied, not only were SERS enhancements of up to 1013 achieved but also imprecision values of less than 10% across the 10-50 pM range using a ratiometric approach and qualitative detection down to 100 aM was achieved. Beyond assessment of SERS substrates, assay designs were investigated and characterized including, label-free techniques and competitive immunoassay formats. Lastly, detecting the SERS signal of multiplexed reporter molecules was investigated. By identifying the analyte and assay constraints the design and optimization of future assays will be aided using this SERS platform technology.

Surface enhanced Raman spectroscopy

nanotechnology

cardiac biomarkers

gold colloid

SERS substrate

Raman spectrosopy

point-of-care diagnostics

Limitations and Improvements in Methods for Precise U-Pb Isotopic Dating of Precambrian Zircon

Das, Abin

11 December 2012

This thesis addresses various issues in U-Pb zircon geochronology, proposing new experimental protocols in conventional chemical abrasion-isotope dilution thermal ionization mass spectrometry or CA-(ID)-TIMS and developing a new method for Pb evaporation-condensation from zircon that allows high precision Pb-Pb age determination on Precambrian samples. Various experiments are also done on zircon to extract U-Pb information by in situ flux aided fusion methods and to optimize a better silica gel Pb-ionization activator. Radiation damage caused by U decay in zircon disrupts its ‘closed system’ behavior leading to the loss of daughter radiogenic Pb and resulting in inaccurate ages. A high temperature thermal annealing procedure has been proposed to prevent such Pb loss. Studies presented here have been carried out using Laser Raman Spectroscopy and Scanning Electron Microscopy to characterize radiation damage and effects of laboratory induced thermal annealing on such damage. Backscattered electron images reveal a variety of textures for ZrO2 overgrowths on zircon annealed at 1450oC. Highly damaged zircon produces finer polycrystalline aggregates (<5µm) than zircon with less damage. Raman spectroscopy indicates that crystals with different levels of radiation damage are only partially restored by annealing at 1000oC for 2–3 or 20 days. Annealing at 1450oC for 1 h results in partial breakdown of zircon but restores Raman peak widths and wave numbers. Raman spectra are much less sensitive to polarization angle for annealed highly damaged grains than for weakly damaged zircon showing that when highly damaged zircon is recrystallized, it becomes a polycrystalline aggregate that pseudomorphs the original single crystal. The whole grain Pb evaporation-condensation method is based on 206Pb-207Pb age analyses where zircon grains are pre-treated at 1450oC to drive out all disturbed Pb and then they are kept at 1600oC for an hour or two during which Pb atoms are evaporated out of the grain and deposited directly into a clean Savillex teflon vial or a wide Re filament. This technique allows the use of a 202Pb-205Pb double spike for precise isotopic fractionation correction. Examples are shown in which application of this technique to zircon from Precambrian samples has successfully yielded sub-million year age precisions.

Uranium-Lead zircon geochronology

Alpha radiation damage

zircon

Raman spectroscopy

0996