Global ETD Search

21	Development of quaternary ammonium based electrolytes for rechargeable batteries and fuel cells Lang, Christopher M. January 2006 (has links) Thesis (Ph. D.)--Chemical and Biomolecular Engineering, Georgia Institute of Technology, 2007. / Kohl, Paul, Committee Chair ; Bottomley, Lawrence, Committee Member ; Eckert, Charles, Committee Member ; Fuller, Tom, Committee Member ; Teja, Amyn, Committee Member.
22	Synthesis and Characterization of Novel Silicone Graft Copolymers January 2016 (has links) abstract: Silicone compounds have a very low surface energy due to highly flexible Si-O-Si backbone and large number of –CH3 groups, but these compounds are extremely hydrophobic and thus have limited applications in aqueous formulations. Modification of such silicone compounds by grafting hydrophilic chains provides a wide range of silicone products called "Silicone Surfactants". Silicone surfactants are surface active agents which get adsorbed at the air-water interface thereby, reducing the interfacial tension. Some of the larger applications of silicone surfactant are in the manufacture of plastic foams, in personal care products and as spreading and wetting agents (Hill, R.M, 2002). In this thesis, a series of silicone surfactant graft copolymers were synthesized via hydrosilylation reaction. Poly(ethylene glycol) (PEG) of different chain length was grafted to a hydrophobic Poly(methylhydrosiloxane) (PMHS) backbone to improve the final hydrophilicity. Also, a positively charged quaternary ammonium salt (allyltriethylammonium bromide) was grafted to the PMHS backbone. The objective of this thesis was to synthesize polymers in predefined ratios of the above mentioned side groups and utilize these polymers to- 1) Study the effect of PEG chain length and its composition on the hydrophilicity of the polymer. 2) Study the effect of PEG: ammonium salt ratio on the surface tension of aqueous systems. Analysis of FT-IR and 1H NMR spectra of the polymers confirmed the predicted structure. The absence of characteristic Si-H absorbance peak at 2160 cm-1 in FT-IR spectra indicates consumption of silane groups along the polymer backbone. The actual moles of the side chain grafted on the backbone are calculated by 1H NMR peak integration. The results of contact angle studies indicated an increase in hydrophilicity with an increase in the composition of PEG in molecule. A 2*2 factorial DOE analysis reported that the fraction of Si-H bonds converted to PEG grafts was the critical factor towards increasing the hydrophilicity (p value of 0.015). Surface tension studies report that the air-water interfacial tension of the synthesized polymers is between 28mN/m – 45mN/m. The amount of Si-H was concluded to be the deciding factor in lowering the surface tension. / Dissertation/Thesis / Masters Thesis Chemical Engineering 2016 Chemical engineering Contact angle PEG-g-PMHS Quaternary ammonium Silicones Surface Tension Surfactant
23	Exploring theoretical origins of the toxicity of organic quaternary ammonium salts towards Escherichia coli using machine learning approaches Naden, Alexandria Olessia January 2014 (has links) Quaternary ammonium salts are surface active bactericides. A mechanism of their biological activity has been well studied experimentally, and it encompasses two stages. The first stage involves electrostatic interactions of polar functional groups of the salts with oppositely charged functional groups on a bacterial cell surface, and the second stage includes incorporation of their lipophilic groups into a bacterial cell membrane. However, despite numerous experimental studies, computational modelling of this mechanism with the aim to support experimental observations with theoretical conclusions, to the author's knowledge, has not yet been reported. In the current study, linear regression models correlating theoretical descriptors of lipophilicity and electronic properties of mono- and disubstituted imidazolium carboxylates with their biological activity towards Escherichia coli have been developed. These models established that biological activity of these salts is governed by the chemical structures of imidazolium cations, and that the centre of this biological activity is located in the long alkyl side chains of the cations. It was also found that these side chains have an intrinsic electronic potential to form internal C-H- -H-C electrostatic interactions when their lengths reach seven carbon atoms. Additionally, the nature of the C-H- -O-C inter-ionic electrostatic interactions in imidazolium carboxylates has been explored via a topological analysis of these interactions in 1-ethyl-3-methylimidazolium acetate. Thus, it was established that these electrostatic interactions are hydrogen bonds. 547
24	Nanocelluloses - surface modification and use in functional materials Salajková, Michaela January 2012 (has links) Cellulose nanocomposites offer interesting potential in terms of improved properties and new functionalities compared with microcomposites. Preparation from colloidal suspensions is promising, since high reinforcement content is possible and a wide range of constituents can be used. In the first study, the challenge is to form a stable suspension of well-dispersed carbon nanotubes (CNT) and nanofibrillated cellulose (NFC) in water and to prepare commingled high CNT content nanopaper structures by filtration. Various surfactants were used to modify CNT. The NFC was stabilized by charged carboxylate groups. A nonylphenol phosphate ester surfactant, NPPE, worked well for CNT and provided a stable and well-dispersed water suspension of CNT and NFC. Field emission scanning electron microscopy (FE-SEM), porosimetry and atomic force microscopy (AFM) were used to characterize nanopaper structure, and tensile properties were measured as well as surface resistivity. The processing route is water based and it is possible to prepare thin coatings as well as thicker films with a combination of low surface resistivity, flexibility in bending and high strength and toughness in tension. As inspired by organo-modified layered silicates, the objective of the second study is to develop an environmentally friendly procedure for the surface modification of cellulose nanocrystals, CNC, using quaternary ammonium salts via adsorption. In order to obtain higher surface charge density on CNC, a new route is developed for preparation of CNC with carboxylic acid groups. Quanternary ammonium cations bearing alkyl, phenyl, glycidyl, and diallyl groups are used to modify CNC to render their surface more hydrophobic. The structure and surface hydrophobicity of unmodified and modified CNC as well as their dispersibility in organic solvent are characterized by AFM, FE-SEM, Fourier-transformed infrared spectroscopy (FT-IR), X-Ray analysis (XDR) and contact angle measurement (CAM). Future work will focus on surface-modified nanocelluloses in composite materials, in order to learn more about surface treatment effects on nanocomposite properties. / Nanokompositer från cellulosa har potential att ge starkt förbättrade egenskaper och ny funktionalitet jämfört med mikrokompositer. De ger även möjlighet till komposittillverkning från kolloidala suspensioner där man kan uppnå hög halt av förstärkningsfasen. Det är också möjligt att välja från en bred flora av lösliga och dispergerbara materialkomponenter. I första studien är utmaningen att skapa en stabil och väldispergerad suspension av kolnanorör (CNT) och nanofibrillerad cellulosa (NFC) i vatten för att genom filtrering framställa nanopapper med interpenetrerande CNT och NFC nätverk. Olika ytaktiva ämnen användes för att modifiera CNT. NFC stabiliserades genom laddade karboxylgrupper på ytan. En nonylfenol fosfatester, NPPE, fungerade bra för CNT och resulterade i en stabil och väldispergerad vattensuspension av CNT och NFC. FE-SEM, densitometri och AFM användes för att karakterisera nanopapperstruktur. Mekaniska egenskaper och ytresistivitet mättes. Processen för framställning av CNT/NFC nanopapper är vattenbaserade och det är möjligt att framställa tunna ytbeläggningar likväl som tjockare filmer. Dessa strukturer har en kombination av låg resistivitet, flexibilitet i böjning liksom hög hållfasthet och seghet i dragbelastning. Syftet med den andra studien är att utgå från organo-modifierade skiktade silikater (leror) för att utveckla en miljövänlig ytmodifieringsmetod för nanocellulosa. För att öka ytladdningstätheten på CNC (nanokristaller från cellulosa) utvecklas ett nytt sätt att skapa karboxylgrupper på ytan. Kvarternära ammoniumsalter med alkyl, fenyl, glycidyl och diallylgrupper används för att göra ytan på CNC mer hydrofob. Ytans struktur och hydrofoba karaktär, liksom dispersionsegenskaper i organiska lösningsmedel, karakteriseras med hjälp av AFM, FE-SEM, FT-IR, XDR och kontaktvinkelmätning. Fortsatt arbete kommer att fokusera på ytmodifierad cellulosa i kompositmaterial, för att utveckla förståelsen för effekter av ytmodifiering på nanokompositers egenskaper / <p>QC 20120302</p> Nanocellulose surfactant surface modification papermaking process quaternary ammonium salt Polymer Chemistry Polymerkemi
25	Pushing the Limits of SARS-CoV-2 Survival: How SARS-CoV-2 Responds to Quaternary Ammonium Compounds and Wastewater Ogilvie, Benjamin Hawthorne 14 April 2021 (has links) SARS-CoV-2 is the virus responsible for the current global pandemic, COVID-19. Because this virus is novel, little is known about its sensitivity to disinfection. In this study, we performed suspension tests against SARS-CoV-2 using three commercially available quaternary ammonium compound (Quat) disinfectants and one laboratory-made 0.2% benzalkonium chloride solution. Three of the four formulations completely inactivated the virus within 15 seconds of contact, even in the presence of a soil load or when diluted in hard water. We conclude that Quats rapidly inactivate SARS-CoV-2, making them potentially useful for controlling SARS-CoV-2 spread in hospitals and the community. In addition to disinfection, little is known about the sensitivity of SARS-CoV-2 to wastewater. A number of researchers have tracked the spread of COVID-19 by using qPCR to look for SARS-CoV-2 RNA in wastewater, but it is unclear how long that RNA lasts or whether that RNA is from intact or inactivated virus. In this study, we added laboratory-grown SARS-CoV-2 to various samples of wastewater and measured its persistence using both qPCR, which detects all viral RNA, and a plaque assay, which detects only infectious virus. The level of infectious virus declined sharply by over 4 log reductions during an 8 day time period, while the level of measurable RNA did not decline significantly. Autoclaving or filtering the wastewater before adding virus attenuated this effect, producing declines of only around 1-3 logs for the infectious virus over 8 days and no significant decline for the RNA. COVID-19 SARS-CoV-2 coronavirus disinfection quaternary ammonium hand sanitizer persistence wastewater Life Sciences
26	Mutations in HIV-1 Vpr Affect Pathogenesis in T-Lymphocytes and Novel Strategies to Contain the Current COVID-19 Pandemic Solis Leal, Antonio 05 February 2021 (has links) Background SARS-CoV-2 is the virus responsible for the current global pandemic, COVID-19. Because this virus is novel, little is known about its sensitivity to disinfection. Methods We performed suspension tests against SARS-CoV-2 using three commercially available quaternary ammonium compound (Quat) disinfectants and one laboratory-made 0.2% benzalkonium chloride solution. Findings Three of the four formulations completely inactivated the virus within 15 s of contact, even in the presence of a soil load or when diluted in hard water. Conclusion Quats rapidly inactivate SARS-CoV-2, making them potentially useful for controlling SARS-CoV-2 spread in hospitals and the community. COVID-19 SARS-CoV-2 Coronavirus Disinfection Quaternary ammonium Hand sanitizer Life Sciences
27	Developing Functionalized Polymer Systems to Promote Specific Interactions and Properties Zander, Zachary K., Zander 23 May 2018 (has links) No description available. Polymers Polymer Chemistry
28	Enhancing the Residual Efficacy of Wood Phytosanitation using a Silane Johnson, Todd Ellis 12 May 2012 (has links) This study investigates use of the organosilane 3-(trimethoxysilyl) propyldimethyl octadecyl ammonium chloride (Si-Quat) as a wood treatment to impart residual moisture and organism control on wood substrates. Study 1, which utilized experimental testing procedures to evaluate mold growth after standardized heat treatment, indicated less surface mold on treated samples. Study 2, which utilized standardized testing procedures to evaluate Si-Quat treated wood’s resistance to subterranean termite attack, indicated greater termite mortality and less feeding on treated wood, as well as increased termite feeding preference for untreated wood. Study 3, which utilized standardized testing procedures to evaluate water repellency, indicated significantly reduced moisture gain at higher silane-based treatment levels in comparison to untreated wood. It is concluded that a silane based treatment utilized in this study can be effective for organism control and the possible supplementation to current phytosanitation of wood packaging materials. termite discoloration quaternary ammonium chloride heat treatment ISPM 15 wood pallets non-native species
29	Bioorganic Investigation of Quaternary Ammonium Compounds: Probing Antibacterial Activity and Resistance Development with Diverse Polyamine Scaffolds Jennings, Megan Christina January 2017 (has links) Quaternary ammonium compounds (QACs) have long served as lead disinfectants in residential, industrial, and hospital settings. Their simple yet effective amphiphilic nature makes them an ideal class of compounds through which to explore antibacterial activity. We have developed novel multiQAC scaffolds through simple and cost-efficient syntheses, yielding hundreds of diverse compounds strategically designed to examine various aspects of antibacterial and anti-biofilm activity, as well as toxicity. Many of these bis-, tris-, and tetraQACs display antibacterial activity 10 to 100 times greater than conventional monoQACs, and are among the most potent biofilm eradicators to date. Through analyzing their activity against several strains, we have uncovered and provided further evidence for key tenets of amphiphilic QAC bioactivity: a balance of hydrophobic side chains with cationic head groups generates optimal antibacterial activity, though toxicity to eukaryotic cells needs to be mitigated. Given their ubiquitous nature and chemical robustness, the overuse of QACs has led to the development of QAC resistance genes that are spreading throughout the microbial world at an alarming rate. These resistant strains, when found in bacterial biofilms, are able to persist in the presence of lead commercial QAC disinfectants, warranting the development of next-generation biocides. Several of our scaffolds were designed with QAC resistance machinery in mind; thus, we utilized these compounds not only as antibacterial agents but also as chemical probes to better understand and characterize QAC-resistance in methicillin-resistant Staphylococcus aureus (MRSA). Our findings support previous postulations that triscationic QACs would retain potency against QAC-resistant strains. Furthermore, we have identified monocationic and aromatic moieties, as well as conformational rigidity, as being more prone to recognition by the resistance machinery. Using our chemical toolbox comprised of QACs of various charge state and scaffold, we explored both the mechanism and scope of QAC-resistance by examining their structure-resistance relationship. Our holistic findings have allowed us to better understand the dynamics of this system towards the design and development of next-generation QACs that will: (1) allow us to better probe the resistance machinery, and (2) remain efficacious against a variety of microbial pathogens. / Chemistry Biochemistry Chemistry Microbiology Antibacterial Resistance Disinfectant Quaternary Ammonium Compound Structure-activity Relationship
30	Reflection Absorption Infrared Spectroscopic Studies of Surface Chemistry Relevant to Chemical and Biological Warfare Agent Defense Uzarski, Joshua Robert 26 February 2009 (has links) Reflection absorption infrared spectroscopy was used as the primary analysis technique to study the interfacial chemistry of surfaces relevant to chemical and biological warfare agent defense. Many strategies utilized by the military to detect and decompose chemical and biological warfare agents involve their interaction with surfaces. However, much of the chemistry that occurs at the interface between the agents and surfaces of interest remains unknown. The surface chemistry plays an important role in efficacy of both detection and decontamination technology, and by obtaining a deeper understanding of that chemistry, researchers might be able to develop more sensitive detection devices and more effective decontamination strategies. Our efforts have focused on three different areas of surface chemistry relevant to chemical and biological warfare agent defense: 1) The development of a surface synthesis strategy to create and control the structure of antibacterial self-assembled monolayers (SAMs). Our work demonstrated a successful strategy for creating SAMs that contain long-chain quaternary ammonium groups, which were synthesized and subsequently characterized using RAIRS and X-ray photoelectron spectroscopy (XPS). 2) The determination of the surface conformation, orientation, and relative surface density of immobilized antimicrobial peptides. Our results revealed that the peptides consisted of tilted (50-60°), α-helices on the surface, regardless of solution conditions. 3) The design and construction of a new ultrahigh vacuum surface science instrument that allows for the study of gas-surface reactions with up to three gases simultaneously. 4) The study of the adsorption of chemical warfare agent simulants to silica nanoparticulate films. Our work demonstrated that the adsorbate structure was dependent on the number of hydrogen-bonding groups, and the adsorption consists of a pressure-dependent two part mechanism. The results presented here will help increase the understanding of the surface chemistry of three interfaces relevant to chemical and biological defense. Future researchers may apply the new information to develop more effective detection and decontamination strategies for chemical and biological warfare agents. / Ph. D. quaternary ammonium cation surface chemistry RAIRS antimicrobial peptides ultrahigh vacuum chemical warfare agent simulants

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