SiC Thin-Films on Insulating Substrates for Robust MEMS-Applications

Chen, Lin

16 May 2003

No description available.

SiC on insulating substrate

LPCVD

ICP etching

MEMS

Fabry-Perot Interferometer

INVESTIGATION OF NICKEL (II)-OXIMATE COMPLEXES THAT REACT WITH MOLECULAR OXYGEN

EDISON, SARA ELIZABETH

01 July 2004

No description available.

Chemistry, Inorganic

Nickel(II)

oximes

oxygen activation

substrate oxidation

catalysis

Environmental Interference and Seismic Communication in Wolf Spiders

Gordon, Shira D.

05 October 2010

No description available.

Biology

wolf spider

communication

noise

substrate

eavesdropping

environment

Characterization of substrate noise coupling, its impacts and remedies in RF and mixed-signal ICs

Helmy, Ahmed

16 November 2006

No description available.

Substrate noise coupling

RFIC

Isolation Techniques

Isolation Design Guides

Analysis and Design of a Low Power 1.2V CMOS Downconversion Mixer Utilising Substrate Biasing / Substrate Biasing Techniques on Gilbert Mixer

Gon, Horace

10 1900

This thesis presents detail theoretical analysis of downconversion Gilbert cell mixer with the improvements on major performance parameters by utilizing different substrate biasing techniques. By modifying the threshold voltage of the switching core, the LO transistors perform more ideally as a perfect switch. It improves the active mixer performances in conversion gain, noise and linearity performances. The techniques are implemented on a 1.2 V low power CMOS downconversion mixer for performance comparisons between simulation and measurements result. They are realized in TSMC 0.18 um CMOS technology. It shows that body-biasing techniques help to increase the switching efficiency of the Gilbert mixer. And a mixer with a better switching provides better performance. With no additional power consumption, the no body effect technique in Design B has shown a 1.5 dB higher in conversion gain, 2 dBm higher in IIP3, and a 0.5 dB lower in NF performance. With the varying biasing technique implemented in Design C, it shows an improvement of 22 dB in conversion gain. Both Design B and C have less than 2 mW power consumption and are suitable for Bluetooth applications. This thesis introduces a stage-by-stage procedure for designing a Gilbert mixer; design tradeoffs at each stage are also discussed. / Thesis / Master of Applied Science (MASc)

mixer

low power

analysis

design

downconversion

substrate bias

Antimony Chalcogenide: Promising Material for Photovoltaics

Rijal, Suman

15 September 2022

No description available.

Physics

Metabolic Adaptations of Ovarian Cancer Metastases to Physiological Conditions and Disease Progression

Compton, Stephanie Lynn Edwards

11 April 2022

Ovarian cancer is the fifth leading cause of all cancer deaths in women and the most lethal gynecologic cancer in the United States. During metastasis, cancer cells exfoliate from the primary tumor and aggregate to form spheroids, enhancing their survival within the peritoneal cavity during dissemination to a secondary outgrowth site. The inability of removal of these aggregates by traditional surgical interventions may contribute to the high recurrence and mortality rate of ovarian cancer diagnosed at late stages. Obesity, particularly abdominal obesity, has been shown to increase ovarian cancer risk and decrease survival. The recruitment of stromal vascular fraction (SVF) present in adipose tissue represents a growth and proliferation advantage to ovarian tumors, and endogenous sphingolipids like sphingosine-1-phosphate are increased in ovarian cancer patients. These conditions, combined with the physiological conditions within malignant ascites (hypoxia and low glucose), represent a physiological environment that can impact the metabolic responses of ovarian cancer spheroids. Here, we investigated the metabolic adaptations of serous ovarian cancer cells across the metastatic cycle and in conditions that mimic those of the peritoneal cavity and malignant ascites. We first investigated the different in metabolic responses between adherent monolayers and 3D spheroids. We confirmed that spheroids have a reduced metabolic rate and drug response that is affected by the incorporation of obese SVF into aggregates. To investigate these changes in the next stages of the metastatic cycle, we used time trials to observe how adherence of spheroids to a secondary site changes metabolic response and substrate utilization in physiological conditions. Adhesion of spheroids showed changes in energy metabolism and substrate utilization, switching from mainly glutamine oxidation to glucose oxidation that could support successful outgrowth. Spheroids also were resilient to culture conditions, even non-permissive conditions such as those found in the peritoneal cavity. Finally, we utilized human malignant ascites from ovarian cancer patients as a further investigation into conditions that imitate in vivo characteristics that could affect spheroid metabolism. Exposure to malignant ascites reduced spheroid viability as well as basal respiration and ATP synthesis. However, spare respiratory capacity was increased, and human spheroids changed their substrate utilization in response to ascites. Taken together, these studies provide an identification of metabolic switches across different stages of ovarian cancer metastasis that contribute to their survival, which represents an emerging target for prevention and treatment for individuals with ovarian cancer. / Doctor of Philosophy / Ovarian cancer is the deadliest reproductive cancer in women, and most women who are diagnosed will die from the disease because of its high recurrence rate and because it is typically detected at late stages. When ovarian cancer metastasizes, cells or cell clusters from the original tumor aggregate together to form balls of cells called spheroids, which move through the abdominal cavity to other sites to grow additional tumors. These spheroids are thought to contribute to recurrence of this cancer, since they cannot be removed by surgery. As these spheroids move through the abdominal cavity, they are exposed to an environment that has a low amount of oxygen and glucose. These spheroids may also be exposed to bioactive lipids and cells from the adipose tissue called stromal vascular fraction, both of which are related to obesity and may help cancer spheroids survive. The survival of these spheroids is in part related to how their metabolism functions, which may help them make energy and the building blocks needed to continue growing and form successful secondary tumors. Identifying how these spheroids change their metabolism at different points during the disease may help identify points that can be targeted to prevent changes in metabolism that could support their growth. This dissertation identified metabolic changes that occur in spheroids, in conditions that are similar to those spheroids would be exposed to in an abdominal cavity. First, we compared single layers of cells to spheroids and found that spheroids had a lower metabolic rate and lower drug response, which may help them survive in the abdominal cavity. Next, we allowed the spheroids to lay down and grow out, like they would when they found a new location during metastasis, to see how their metabolism changed and what substances they used to make energy in conditions that mimicked the abdominal cavity. As spheroids adhered, they changed their energy metabolism and switched the substances they used to make energy, all while continuing to survive and grow out even in conditions that were not supportive. These switches could help them grow out and successfully metastasize. Lastly, we used ascites fluid from human ovarian cancer patients and treated spheroids with this to see how their metabolism changed in response. While some aspects of metabolism and survival was reduced, their ability to increase their metabolism when stressed increased and human spheroids used nutrients to make energy differently. Overall, we show that across the stages of metastasis, ovarian cancer spheroids can change their metabolism in response to their environment. Identifying these metabolic switches helps us understand how successful metastasis happens, and can inform future targets to slow or prevent metastasis, prolonging the life of women who have been diagnosed with ovarian cancer.

Ovarian cancer

metabolism

respiration

spheroid

hypoxia

substrate utilization

ascites

Nitrogen Fate and Transformations in the Production of Containerized Specialty Crops

Brown, Forrest Jackson

07 May 2024

Nitrogen (N) fertilizer is a required mineral nutrient in containerized crop production that is necessary for crop growth and development. Due to production aspects, the N added to crops far exceeds the amount that the plant uses and such inefficiency results in adverse environmental impacts related to N gaseous and aqueous emissions from containers on the production site. Growers are responsible for optimizing nutrient usage in crop production. Three studies were conducted to investigate and better understand the fate of applied N fertilizers, the transformations associated with individual N sources, and the influence of substrate texture on losses of aqueous and gaseous N species. The first study conducted a mass balance looking at the four major avenues of N fate in an open-air container production setting (plant uptake, immobilized or bound N in a pine bark substrate, leached aqueous N, and gaseous emissions of N), the mass balance was speciated to measure applied and intermediary forms of N fertilizer species to provide insight into the overall fate of applied N. Show Off® Forsythia ×intermedia' Mindor' were grown using two control-release fertilizer (CRF) treatments [AN (ammonium-nitrate based) or UAN (urea ammonium-nitrate)] products. This study determined that 97% of the released N from the CRF treatments was lost via aqueous or gaseous pathways. The aqueous losses were inferred to be predominately composed of NO3-N, while the gaseous emissions were inferred to be predominately lost as inert nitrogen gas (N2). During a second experiment, individual N sources treatments [urea (CH4N2O), ammonium (NH4+), and nitrate (NO3-)] were applied to established containers of At LastⓇ Rosa x 'HORCOGJIL' grown in a pine bark substrate in either open wall high tunnel or a glass greenhouse to determine subsequent reaction sequence and fate based on applied N source. By applying an individual form of N it was determined that based on the N source applied, a sequential set of reactions occurs based on the N source. This study determined that the reactive N gaseous species occurred from the hydrolysis of CH4N2O-N to NH4+ and the nitrification of NH4+ to NO3- and then the denitrification of NO3- to N2. Hibiscus moscheutos' Vintage wine' was grown in either a coarse or fine texture substrate utilizing either a water-soluble fertilizer or a CRF to compare the influence of pine bark texture on N leachate losses and RN gaseous emissions. There were few differences between the two substrate texture treatments related to aqueous or gaseous N losses. In both experiments, the Hibiscus grown in the fine texture substrate resulted in higher above and below-ground biomass at experimental termination. Working with growers to develop best management practices will help to improve the use of N fertilizers and impact growers economically, while simultaneously reducing losses leading to less environmental impact on the areas surrounding production sites. / Doctor of Philosophy / Nitrogen (N) fertilizer is a crucial mineral nutrient input to produce container crops, however excessive application can have detrimental effects on the environment including gaseous N emissions and N leaching leading to water pollution. Therefore, three studies were conducted to investigate N losses during production and potential mitigation strategies using common management practices in the production of container crops. During the first study investigating how N fertilizer is lost from production, results showed that a significant portion of the N added to the containers is either emitted from the containers into the atmosphere or leached from the container. Only a small fraction of the applied N was utilized by the plants for growth and development. The second study investigated the reactions and transformations of different N fertilizers sources. When applying single N sources urea (CH4N2O), ammonium (NH4+), or nitrate (NO3-) result in a set of sequential reactions that occur based on the applied N source. Urea is hydrolyzed via CH4N2O hydrolysis leading to the formation of NH4+ which is nitrified via nitrification to NO3- which is denitrified via denitrification leading to the production of N2 gas. In the final study two pine bark substrate classes were compared when using either a water-soluble fertilizer (WSF) or a controlled-release fertilizer (CRF). Surprisingly there were only a few differences between the two substrate treatments in either the WSF or CRF studies. This body of work show the importance of investigating N fertilizer usage in container crop production. Collaboration between researchers and growers is crucial to develop management practices that maximize the associated economic input of N fertilizers and minimize losses of N that are detrimental to the environment.

Containerized crop

control-release fertilizer

denitrification

nitrogen gasses

soilless substrate

Abrasive Blasting with Post-Process and In-Situ Characterization

Mills, Robert Jeffrey

25 July 2014

Abrasive blasting is a common process for cleaning or roughening the surface of a material prior to the application of a coating. Although the process has been in practice for over 100 years, the lack of a comprehensive understanding of the complex interactions that exist with the process can still yield an inferior surface quality. Subsequently, parts can be rejected at one of many stages of the manufacturing process and/or fail unexpectedly upon deployment. The objective of this work is to evaluate the effect of selected input parameters on the characteristics of the blasted surface characteristics so that a more useful control strategy can be implemented. To characterize surface roughness, mechanical profilometry was used to collect average roughness parameter, Ra. Decreasing blast distance from 6” to 4” gave ΔRa = +0.22 µm and from 8” to 6” gave ΔRa = +0.22 µm. Increasing blast pressure from 42 psi to 60 psi decreased the Ra by 0.33 µm. Media pulsation reduced Ra by 0.56 µm and the use of new media reduced Ra by 0.47 µm. Although blasting under the same conditions and operator on different days led to ΔRa due to shorter blast times, there was no statistically significant variance in Ra attributed to blasting on different days. Conversely, a ΔRa = +0.46 µm was observed upon blasting samples with different cabinets. No significant ΔRa was found when switching between straight and Venturi nozzles or when using different operators. Furthermore, the feasibility of fiber optic sensing technologies was investigated as potential tools to provide real time feedback to the blast machine operator in terms of substrate temperature. Decreasing the blast distance from 6” to 4” led to ΔT = +9.2 °C, while decreasing the blast angle to 45° gave ΔT= -11.6 °C for 304 stainless steel substrates. Furthermore, increasing the blast pressure from 40 psi to 50 psi gave ΔT= +15.3 °C and changing from 50 psi to 60 psi gave ΔT= +9.9 °C. The blast distance change from 8” to 6” resulted in ΔT = +9.8 °C in thin stainless steel substrate temperature. The effects of substrate thickness or shape were evaluated, giving ΔT= +7.4 °C at 8” distance, ΔT= +20.2 °C at 60 psi pressure, and ΔT= -15.2 °C at 45° blasting when comparing thin stainless steel against 304 stainless steel (thick) temperatures. No significant ΔT in means was found when going from 6” to 8” distance on 304 stainless steel, 40 psi and 60 psi blasting of thin SS, as well as angled and perpendicular blasting of thin SS. Comparing thick 304 and thin stainless steel substrates at a 6” blast distance gave no significant ΔT. / Master of Science

abrasive blasting

media

substrate

profilometry

roughness

Temperature

optical fibers

Measurement of Phytase Activity in a Clymer Forest Soil Using the TInsP5 Probe

Huang, Zirou

26 August 2009

Measurement of soil phytase activity (PA) and delineation of the impact of this important phosphomonoesterase on the P-cycling process in soil and sediments suffer from the lack of a reliable assay. A method for measuring PA in soil that promises to be accurate and reliable has been recently published. The method involves the use of a novel chromophoric analog of phytic acid, referred to as T(tethered)InsP5 (5-O-[6-(benzoylamino)hexyl]-D-myo-inositol-1,2,3,4,6-pentakisphosphate). This study was conducted to measure PA in a Clymer forest soil, which contained over twice the amount of soil organic C as previously tested soils, using the TInsP5 PA assay. This investigation specifically addresses: (1) the development of a soil dilution technique for determining maximal PA, (2) identification of previously unsubstantiated soil-produced dephosphorylated intermediate probe species, (3) the impact of increasing assay buffer pH on soil PA and (4) testing stability of the probe's amide bond in a highly (bio)active forest soil. PA assays were conducted by measuring dephosphorylation of TInsP5 in citrate-acetate buffered (pH 4.2) active and autoclaved (Control) soil suspensions. Phosphorylated probe intermediates (i.e., TInsP4, TInsP3, TInsP2 and TInsP1) and T-myo-inositol were extracted from samples of soil suspension following incubation. Probe species were quantified using reversed phase high-performance liquid chromatography (RPHPLC) with UV detection. PA was calculated based on a mass balance approach. A soil dilution technique was developed to address the challenge of determining maximal PA in soils containing higher organic matter content. In the initial report on use of the TInsP5 method for measuring PA in soil, two "soil-generated" UV-adsorbing compounds (designated Y and Z) were observed, but never confirmed as probe species. The experimental evidence presented in this report supports inclusion of compound Y as a phosphorylated probe intermediate species (i.e. TInsPy), based primarily on its UV adsorption spectra (diode-array detection analysis). Compound Z could not be substantiated as a probe species based on the evidence presented in this study. PA of Claymer forest soil decreased with an increase in assay buffer pH. Further, the probe's amide bond linkage was stable in a forest soil exhibiting high PA. / Master of Science

artificial substrate

chromophoric tethered phytate

phytase activity assay

Soil