Global ETD Search

261	Analytical techniques for differentiating huacaya and suri alpaca fibers Shim, Sohie 13 November 2003 (has links) No description available. DSC scanning electron microscopy EDS IR spectroscopy alpaca fibers cortical cells
262	Nanocomposite Dispersion: Quantifying the Structure-Function Relationship Gibbons, Luke J. 04 November 2011 (has links) The dispersion quality of nanoinclusions within a matrix material is often overlooked when relating the effect of nanoscale structures on functional performance and processing/property relationships for nanocomposite materials. This is due in part to the difficulty in visualizing the nanoinclusion and ambiguity in the description of dispersion. Understanding the relationships between the composition of the nanofiller, matrix chemistry, processing procedures and resulting dispersion is a necessary step to tailor the physical properties. A method is presented that incorporates high-contrast imaging, an emerging scanning electron microscopy technique to visualize conductive nanofillers deep within insulating materials, with various image processing procedures to allow for the quantification and validation of dispersion parameters. This method makes it possible to quantify the dispersion of various single wall carbon nanotube (SWCNT)-polymer composites as a function of processing conditions, composition of SWCNT and polymer matrix chemistry. Furthermore, the methodology is utilized to show that SWCNT dispersion exhibits fractal-like behavior thus allowing for simplified quantitative dispersion analysis. The dispersion analysis methodology will be corroborated through comparison to results from small angle neutron scattering dispersion analysis. Additionally, the material property improvement of SWCNT nanocomposites are linked to the dispersion state of the nanostructure allowing for correlation between dispersion techniques, quantified dispersion of SWCNT at the microscopic scale and the material properties measured at the macroscopic scale. / Ph. D. Nanocomposite dispersion Single wall carbon nanotube Nanotube dispersion quantification
263	An Improved Thermogravimetric Analysis Method for Respirable Coal Mine Dust and Comparison to Results by SEM-EDX Agioutanti, Eleftheria 24 July 2019 (has links) It has long been known that chronic exposures to high concentrations of respirable coal mine dust can lead to the development of lung diseases such as Coal Worker's Pneumoconiosis, commonly referred to as "black lung", and silicosis. Since the mid-1990s, an alarming resurgence of diseases has been documented in central Appalachia, where underground mining often necessitates significant extraction of rock strata along with the thin seams of coal. These circumstances have prompted concern over if or how changing dust composition might be a factor in contemporary disease prevalence. Until now, the total mass concentration and quartz mass fraction of respirable dust have been regulated and monitored in US coal mines. Unfortunately, however, these two metrics alone do not paint a full picture of dust composition. Earlier work in the author's research group established a preliminary thermogravimetric analysis (TGA) method for coal mine dust. The method is intended to allow estimation of three key mass fractions of the dust from separate sources: coal from the coal strata being mined; non-carbonate minerals from the rock strata being mined or drilled; and carbonates that are primarly sourced from application of rock dust products to the mine floor or ribs. However, accuracy of the preliminary method was substantially limited by poor dust recovery from the fibrous filter media used for sample collection. This thesis includes two studies: The first study aims to establish an improved TGA method. It uses smooth polycarbonate (PC) filters for dust sampling and a modified thermal ramping routine. The method is verified using laboratory-generated respirable dust samples. In the second study, the improved TGA method is used to analyze 75 respirable mine dust samples, collected in 15 US mines. Replicate samples are also analyzed by scanning electron microscopy using energy dispersive X-ray (SEM-EDX). TGA and SEM-EDX results are compared to gain insights regarding the analytical methods and general trends in dust composition within and between mines. / Master of Science / It has long been known that chronic exposures to excessive respirable coal mine dust can lead to the development of lung diseases such as Coal Worker’s Pneumoconiosis (“Black Lung”) and silicosis. Disease rates in central Appalachia have shown an alarming and unexpected increase since the mid-1990s, despite declining dust concentrations evident from regulatory compliance monitoring data. Clearly, there is a need to better understand coal mine dust composition, which will require additional analytical methods. Thermogravimetric analysis (TGA) has been proposed as one possible method, because it should allow estimation of three key dust components from separate sources: coal from the coal strata being mined; non-carbonate minerals from the rock strata being mined or drilled; and carbonates from application of rock dust products to the mine floor and ribs. However, preliminary work with TGA showed limited accuracy, mostly due to sampling materials. In this thesis, two studies were performed. The first study aims to establish an improved TGA method using smooth, polycarbonate (PC) filters. The second study demonstrates the method on a large number of mine dust samples, and compares the results to those gained by an alternative method that uses electron microscopy. Thermogravimetric Analysis (TGA) Scanning Electron Microscopy (SEM) Respirable Dust Coal Worker's Pneumoconiosis (CWP)
264	Morphological and Physiological Characteristics that Contribute to Insecticide Resistance in Bed Bug (Cimex lectularius L.) Eggs Delong, Brittany E. 08 July 2014 (has links) Although bed bug eggs are a difficult life stage to control with our currently labeled insecticides, few studies have examined how bed bug egg morphology and physiology is potentially related to pesticide resistance in bed bug eggs. Bed bug egg morphological features were examined using scanning electron microscopy (SEM) and the chorion and respiration structures were identified. Scanning electron microscopy photographs and bed bug egg measurements indicated there were no morphological differences between different bed bug egg strains (susceptible and resistant). Bed bug egg respiration rates measured by the amount of oxygen consumed (standard metabolic rate; SMR) also indicated there was no difference in SMR between different bed bug egg strains. Water conservation during respiration is vital to terrestrial insects. Therefore, similar patterns would be expected between egg water loss and respiration rates. However, susceptible strain eggs lost more water than one resistant strain of bed bug eggs, which was dissimilar from the respiration results, indicating that bed bug egg water loss and respiration are not directly related. Dose- response bioassays using two insecticide formulations (Temprid; imidacloprid/β-cyfluthrin, and Transport; acetamiprid/bifenthrin) indicated that bed bug eggs collected from pyrethroid resistant adult bed bug strains are also highly resistant. RNA sequencing of bed bug eggs from two resistant strains indicated that egg resistance may be directly related to the overexpression of multiple genes associated with insecticide resistance. / Master of Science in Life Sciences Cimex lectularius L. Bed Bug Eggs Scanning Electron Microscopy Respirometry Insecticide Resistance RNA-Seq
265	Ch4- IODP EXP 341 U-Pb Zircon Results for Lonestones Wai Kehadeezbah Allen (14671736) 17 May 2024 (has links) <p>This dataset includes U-Pb zircon summary excel file with datatables for all lonestones analyzed.This file also sorts data to include information of Rim and Core analyses were appropriate.</p> <p><br></p> <p>In addition, raw data for each individual sample are included that have detailed information regarding parameters during each analytical session. </p> <p><br></p> <p>All samples were analyzed at the University of Arizona Laserchron Center (NSF-EAR 1649254)</p> <p><br></p> <p>High Resolition Scanning Electron Microscopy Images are also included that were imaged at the University of Arizona Laserchron Center</p> <p><br></p> Geochronology U-Pb zircon ages Gulf of Alaska IODP Expedition 341 dropstones scanning electron microscopy
266	A new combined approach using confocal and scanning electron microscopy to image surface modifications on quartzite Pedergnana, A., Ollé, A., Evans, Adrian A. 10 February 2020 (has links) Yes / Confocal microscopy has been increasingly employed in the field of traceology to acquire metrological data of surface changes on a micro-scale. However, its advantages for a traditional visual inspection of use-wear are rarely highlighted. As traditional optical microscopy (OM) has proven unable to entirely fulfil the prerequisites for an ideal observation of highly reflective and irregular materials, alternative ways for providing better observation conditions must be sought. In this contribution, we explore the combination of laser scanning confocal (LSCM) and scanning electron microscopy (SEM) micro-graphs for the visual characterisation of wear on quartzite and evaluate the potential of both techniques. / AHRC Fragmented Heritage project (AH/L00688X/1) at the University of Bradford, and of the MICINN-FEDER (PGC2018-093925-B-C32), the AGAUR (SGR 2017-1040) and the URV (2018PFR-URV-B2-91) projects at IPHES-URV. One of the authors (A.P.) was beneficiary of a Catalan pre-doctoral grant (2014FI B 00539), at the Rovira i Virgili University (URV), the IPHES and the Muséum national d’Histoire naturelle of Paris. Laser scanning confocal microscopy Scanning electron microscopy Use-wear analysis Polished surfaces Quartzite
267	Three dimensional reconstruction metrology by combinatory multiple parameter characterization and scanning probe microscopy Houge, Eric C. 01 April 2001 (has links) No description available. Measurement Scanning electron microscopy Scanning probe microscopy Engineering Engineering Science and Materials
268	E-SEM Characterization of Escherichia coli Biofilms Grown on Copper- and Silver-Alloyed Stainless Steels over a 48 - McMullen, Amelia Marie 01 June 2018 (has links) The formation of bacterial biofilms on surfaces and their subsequent biofouling pose extensive safe and healthy concerns to a variety of industries. Biofilms are ubiquitous, and the biofilm state is considered the default mode of growth for the majority of the world's bacteria population. Once mature, biofilms are difficult to remove completely and have improved resistance against antibacterial agents. Given this, there has been significant interest to mitigate or at least manage biofilm formation on surfaces. One such method has been through the material design of surfaces, and to the interest of this study, through the development of antimicrobial stainless steels. Stainless steel is not an inherently antimicrobial material. Stainless steels alloyed with small amounts of either copper (Cu) or silver (Ag), both well-known natural antimicrobial agents, have been investigated since their initial development in the late 1990's onward. This class of materials have been proven to show significant antimicrobial effect over their traditional counterparts without compromising the characteristic mechanical properties of the stainless steels. However, most of the antimicrobial assessments for these materials documented within literature are conducted over a 24-hour timeframe and do not adequately account for the biofilm mode of growth. As so, this study aimed to assess how biofilms grow on this class of antimicrobial steels over a longer duration of growth and under growth conditions which more adequately modeled the biofilm mode of life. The same strain of Escherichia coli commonly used in antimicrobial surface testing, ATCC 8739, was grown on submicron-polished coupons of a ferritic Cu-alloyed stainless steel (1.50 wt. % Cu), an austenitic Ag-alloyed stainless steel (0.042wt. % Ag), and a standard 304 series stainless steel, used as a baseline. Following ASTM-E2647-13, the E. coli/SS coupons were grown using a drip flow bioreactor under low shear conditions at either ambient temperature or 37 ± 3 degrees C with a batch phase of 6 hours and a continuous phase of 48 hours up to 96 hours. Directly after harvesting, the coupons were analyzed with an Environmental Scanning Electron Microscope (E-SEM) under low vacuum with a water vapor environment. The effect of surface chemistry and alloy microstructure, surface roughness, rinsing the surfaces prior to inoculation and after harvesting, temperature, and growth duration on the resulting E. coli biofilms were all investigated in some capacity. Growth on the submicron finished surfaces indicated there were no significant differences between the biofilms grown on the three different steel compositions. Bacterial attachment appeared non-preferential to surface chemistry or alloy microstructure, suggesting that E. coli interacted with the surfaces effectively the same under the given growth conditions. To account for apparent randomness in bacterial attachment, it is hypothesized that the surface features of interest were on a size scale irrelevant to the size of single bacterial cells. To account for the lack of an observed biocidal effect from the Cu- and Ag-alloyed stainless steels, it is hypothesized that an organic conditioning film which developed on the surfaces from the fluid environment may have effectively inhibited the release of Cu and Ag ions from the steel surfaces. / MS / Bacteria frequently self-organize into what are commonly called bacterial biofilms, or an aggregation of bacterial cells that attach to a surface and which are embedded within a self-generated matrix of polymeric substances, such as proteins and polysaccharides. The biofilm state offers a lot of survival advantages to bacteria, and once biofilms form on a surface they are very difficult to remove. The formation of bacterial biofilms on surfaces and their subsequent biofouling pose extensive safe and healthy concerns to a variety of industries. There has been significant interest to stop or at least manage biofilm formation on surfaces. One such method has been through the design of surfaces, and to the interest of this study, through the development of antimicrobial stainless steels. Stainless steel is not an inherently antimicrobial material. Stainless steels which include small amounts of either copper or silver have been proven to show a significant antimicrobial effect over their traditional stainless steel counterparts without compromising the other desirable properties of the steels. However, most of the documented antimicrobial assessments for these materials have been conducted over a 24-hour timeframe and do not adequately account for the biofilm mode of growth. This study aimed to assess how biofilms grow on this class of steels over a longer duration of growth and under growth conditions which more adequately modeled the biofilm mode of life. This was done by growing a single strain of E. coli bacteria onto coupons of these stainless steel materials for either a 48-hour or a 96-hour timeframe within a low-flow, continuously-fed bioreactor. The coupons were visualized with an environmental scanning electron microscope to assess the effect of the material properties on the observed biofilms grown during this study. Overall there were little differences observed between the E. coli biofilms grown on the copper-containing stainless steel, the silver-containing stainless steel, and the standard stainless steel used within this study. Mirror finish smooth surfaces were needed in order to adequately visualize the steel coupons. The bacteria appeared to attach randomly without any preference for steel surface chemistry or other surface features. This suggested that under the given growth conditions the bacteria interacted with the smooth steel surfaces the same. To account for this randomness, it is hypothesized that the relevant surface features were significantly smaller than the size of single bacterial cells. E. coli cells are between 1 – 2 micrometers long and 0.5 – 1 micrometers in diameter. There was also no antimicrobial effect observed on the copper-containing and silver-containing stainless steels. To account for the lack of an observed antimicrobial effect, it is hypothesized that a conditioning film of carbon-based molecules formed on the surface of the steels from the liquid growth medium environment, preventing bacterial cells from being damaged by the copper and silver within the steel surfaces. E. coli Biofilms Antimicrobial Stainless Steels Drip Flow Bioreactor
269	Preparation, characterization and performance evaluation of Nanocomposite SoyProtein/Carbon Nanotubes (Soy/CNTs) from Soy Protein Isolate Sadare, Olawumi Oluwafolakemi 04 1900 (has links) Formaldehyde-based adhesives have been reported to be detrimental to health. Petrochemical-based adhesives are non-renewable, limited and costly. Therefore, the improvement of environmental-friendly adhesive from natural agricultural products has awakened noteworthy attention. A novel adhesive for wood application was successfully prepared with enhanced shear strength and water resistance. The Fourier transmform infrared spectra showed the surface functionalities of the functionalized carbon nanotubes (FCNTs) and soy protein isolate nanocomposite adhesive. The attachment of carboxylic functional group on the surface of the carbon nanotubes (CNTs) after purification contributed to the effective dispersion of the CNTs in the nanocomposite adhesive. Hence, enhanced properties of FCNTs were successfully transferred into the SPI/CNTs nanocomposite adhesive. These unique functionalities on FCNTs however, improved the mechanical properties of the adhesive. The shear strength and water resistance of SPI/FCNTs was higher than that of the SPI/CNTs. SEM images showed the homogenous dispersion of CNTs in the SPI/CNTs nanocomposite adhesive. The carbon nanotubes were distributed uniformly in the soy protein adhesive with no noticeable clusters at relatively reduced fractions of CNTs as shown in the SEM images, which resulted into better adhesion on wood surface. Mechanical (shear) mixing and ultrasonication with 30 minutes of shear mixing both showed an improved dispersion of CNTs in the soy protein matrix. However, ultrasonication method of dispersion showed higher tensile shear strength and water resistance than in mechanical (shear) mixing method. Thermogravimetric analysis of the samples also showed that the CNTs incorporated increases the thermal stability of the nanocomposite adhesive at higher loading fraction. Incorporation of CNTs into soy protein isolate adhesive improved both the shear strength and water resistance of the adhesive prepared at a relatively reduced concentration of 0.3%.The result showed that tensile shear strength of SPI/FCNTs adhesive was 0.8 MPa and 7.25MPa at dry and wet state respectively, while SPI/CNTs adhesive had 6.91 MPa and 5.48MPa at dry and wet state respectively. There was over 100% increase in shear strength both at dry and wet state compared to the pure SPI adhesive. The 19% decrease in value of the new adhesive developed compared to the minimum value of ≥10MPa of European standard for interior wood application may be attributed to the presence of metallic particles remaining after purification of CNTs. The presence of metallic particles will prevent the proper penetration of the adhesive into the wood substrate. The type of wood used in this study as well as the processing parameters could also result into lower value compared to the value of European standard. Therefore, optimization of the processing parameter as well as the conversion of carboxylic acid group on the surface of the CNTs into acyl chloride group may be employed in future investigation. However, the preparation of new nanocomposite adhesive from soy protein isolate will replace the formaldehyde and petrochemical adhesive in the market and be of useful application in the wood industry. / Civil and Chemical Engineering / M. Tech. (Chemical Engineering) Adhesive Soy protein Isolate Carbon nanotubes(CNTs) Shear strength Nanocomposite Scanning electron microscopy (SEM) Fourier transform infra-red Thermo gravimetric analysis Performance evaluation Wood 620.5 Adhesives Nanocomposites (Materials) Nanotechnology Nanotubes Carbon nanotubes Scanning electron microscopy Fourier transform infrared spectroscopy
270	Preparation, characterization and performance evaluation of Nanocomposite SoyProtein/Carbon Nanotubes (Soy/CNTs) from Soy Protein Isolate Sadare, Olawumi Oluwafolakemi 04 1900 (has links) Formaldehyde-based adhesives have been reported to be detrimental to health. Petrochemical-based adhesives are non-renewable, limited and costly. Therefore, the improvement of environmental-friendly adhesive from natural agricultural products has awakened noteworthy attention. A novel adhesive for wood application was successfully prepared with enhanced shear strength and water resistance. The Fourier transmform infrared spectra showed the surface functionalities of the functionalized carbon nanotubes (FCNTs) and soy protein isolate nanocomposite adhesive. The attachment of carboxylic functional group on the surface of the carbon nanotubes (CNTs) after purification contributed to the effective dispersion of the CNTs in the nanocomposite adhesive. Hence, enhanced properties of FCNTs were successfully transferred into the SPI/CNTs nanocomposite adhesive. These unique functionalities on FCNTs however, improved the mechanical properties of the adhesive. The shear strength and water resistance of SPI/FCNTs was higher than that of the SPI/CNTs. SEM images showed the homogenous dispersion of CNTs in the SPI/CNTs nanocomposite adhesive. The carbon nanotubes were distributed uniformly in the soy protein adhesive with no noticeable clusters at relatively reduced fractions of CNTs as shown in the SEM images, which resulted into better adhesion on wood surface. Mechanical (shear) mixing and ultrasonication with 30 minutes of shear mixing both showed an improved dispersion of CNTs in the soy protein matrix. However, ultrasonication method of dispersion showed higher tensile shear strength and water resistance than in mechanical (shear) mixing method. Thermogravimetric analysis of the samples also showed that the CNTs incorporated increases the thermal stability of the nanocomposite adhesive at higher loading fraction. Incorporation of CNTs into soy protein isolate adhesive improved both the shear strength and water resistance of the adhesive prepared at a relatively reduced concentration of 0.3%.The result showed that tensile shear strength of SPI/FCNTs adhesive was 0.8 MPa and 7.25MPa at dry and wet state respectively, while SPI/CNTs adhesive had 6.91 MPa and 5.48MPa at dry and wet state respectively. There was over 100% increase in shear strength both at dry and wet state compared to the pure SPI adhesive. The 19% decrease in value of the new adhesive developed compared to the minimum value of ≥10MPa of European standard for interior wood application may be attributed to the presence of metallic particles remaining after purification of CNTs. The presence of metallic particles will prevent the proper penetration of the adhesive into the wood substrate. The type of wood used in this study as well as the processing parameters could also result into lower value compared to the value of European standard. Therefore, optimization of the processing parameter as well as the conversion of carboxylic acid group on the surface of the CNTs into acyl chloride group may be employed in future investigation. However, the preparation of new nanocomposite adhesive from soy protein isolate will replace the formaldehyde and petrochemical adhesive in the market and be of useful application in the wood industry. / Civil and Chemical Engineering / M. Tech. (Chemical Engineering) Adhesive Soy protein Isolate Carbon nanotubes (CNTs) Shear strength Nanocomposite Scanning electron microscopy (SEM) Fourier transform infra-red Thermo gravimetric analysis Performance evaluation Wood 620.5 Adhesives Nanocomposites (Materials) Nanotechnology Nanotubes Carbon nanotubes Scanning electron microscopy Fourier transform infrared spectroscopy

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