Global ETD Search

501	Hydrogel/Polymer Micelles Composites Derived from Polymerization of Microemulsions for Oral Drug Delivery Chen, Li 04 October 2013 (has links) No description available. Biomedical Research Chemical Engineering Polymers
502	Chemistry of Bismuth, Chromium and Magnesium Complexes and Their Applications in the Ring-Opening Polymerization of Cyclic Esters and Epoxides Balasanthiran, Vagulejan 13 October 2015 (has links) No description available. Chemistry Polymer Chemistry Polymers
503	Growth and Characterization of Magnesium Single Crystal for Biodegradable Implant Material Application Joshi, Madhura A. January 2015 (has links) No description available. Materials Science High Purity Magnesium Single Crystal Biodegradable Implants Surface Treatments Electrochemial Corrosion Testing Directional solidification
504	Development of waterborne and mild curing DWRs, formulated with fully bio-based substances / Utveckling av vattenburna, lättaktiverade och vattenavvisande textilimpregneringar som är tillverkade från helt biobaserade råvaror van Overmeeren, Johannes R. S. January 2020 (has links) ”Durable water repellents (DWR) är textilimpregneringar som bidrar med vattenavvisande egenskaper som håller länge på funktionella tyg. Tyvärr är dessa hydrofobiska ytbehandlingar vanligtvis en källa till skadliga och persistenta kemikalier och de även är producerade från fossilbaserade resurser. Eftersom medvetenheten kring de här problemen har ökat, har innovativa, miljövänliga och biologiskt nedbrytbara alternativ tagits fram. Hittills finns dock inga produkter gjorda av 100% förnybara råvaror. I ett försök att utveckla en biobaserad, icke-giftig DWR som aktiveras under milda förhållanden, lades fokus på utveckling av en lagringsstabil sprayimpregneringsprodukt för hemmabruk. Vid formulering av emulsionerna/dispersionerna utvärderades en stor mängd biobaserade och kommersiellt tillgängliga hydrofobiska och amfifila molekyler med avseende den vattenavvisande effekt som de bidrog med på den behandlade textilen. Samtidigt bedömdes de producerade formuleringarna noggrant för att skapa förståelse om effekterna från ingredienserna och deras relation till produktens stabilitet. De kandidatprodukter som valdes ut och undersöktes vidare hade lovande vattenavvisande egenskaper och visade rimlig hållbarhetstid på åtminstone en månad i 40 °C. Standardiserade sprayscores på 3 (där 1 är sämst och 5 är bäst) nåddes efter 24 timmars hängtorkning i rumstemperatur. Dessutom uppnåddes sprayscore på 5 efter en kort, icke-industriell torktumling på låg temperatur och den behölls efter minst tio tvättar på syntetiska textiler. Utvalda produkter påverkade inte märkbart tygets andningsförmåga och majoriteten hade ingen influens på textilens mjukhet och färg. Förutom uppskalningsexperiment och partikelstorleksmätningar, granskades resultat med en tillämpningsstudie av formuleringarna på femton olika tygtyper. Produkternas effekter på utseende och känsla dokumenterades för de olika textilierna. Egenskaper som kontaktvinklar, sprayscores och tvättbeständighet bestämdes och jämfördes med en kommersiellt tillgänglig produkt. / Durable water repellents (DWR) are textile finishes that provide long-lasting water repelling properties to functional garments. However, these hydrophobic finishes are commonly a source of polluting and persistent chemicals and are produced from fossil resources. As a result of increasing awareness, innovation towards environmentally friendly and biodegradable alternatives has progressed, yet no 100% renewable sourced products are available. In an attempt to create a bio-based, non-toxic DWR, that is curable under mild conditions, focus was put on the development of a shelf stable spray impregnation product intended for consumer use. By formulating dispersion/emulsion systems, a wide variety of commercially available, renewable sourced amphiphilic and hydrophobic molecules were evaluated on their effect on the water repelling performance of treated textile fabrics. Simultaneously, the produced systems were assessed carefully to create understanding on the effect of substances and their corresponding ratios on the stability. Promising candidate products that were selected for further investigation showed reasonable stability for 1 month at 40 °C. Industrial standard spray ratings of 3 (where 1 is worst and 5 is best) after hang drying at room temperature could be reached within 24 hours. On top of that, spray ratings of 5 could be reached after short time, non-industrial tumble drying at low temperatures, which could even be retained for at least ten laundering cycles on synthetic textiles. The selected finishes did not have a measurable effect on the breathability of the treated fabrics, while the majority did not considerably affect the hands-feeling or colour of the textiles. Besides several scaling up experiments and particle size measurements, extrapolation of the findings was carried out by testing the developed formulations on fifteen different types of textiles. Effects on appearance and feel were documented, additionally, contact angle, spray score, and wash durability were determined and compared with a commercially available product. Durable water repellents Bio-based Biodegradable Two-phase systems Fluorine-free Functional textile finishes Vattenavvisning Bio-baserad Biologiskt nedbrytbar Fluorkarbonfri Funktionella textilbehandlingar Polymer Technologies Polymerteknologi
505	Profiling of Microbial Communities, Antibiotic Resistance, Functional Genes, and Biodegradable Dissolved Organic Carbon in a Carbon-Based Potable Water Reuse System Blair, Matthew Forrest 17 March 2023 (has links) Water reuse has become a promising alternative to alleviate stress on conventional freshwater resources in the face of population growth, sea level rise, source water depletion, eutrophication of water bodies, and climate change. Potable water reuse intentionally looks to purify wastewater effluent to drinking water quality or better through the development and implementation of advanced treatment trains. While membrane-based treatment has become a widely-adopted treatment step to meet this purpose, there is growing interest in implementing treatment trains that harness microorganisms as a more sustainable and less energy-intensive means of removing contaminants of emerging concern (CECs), through biological degradation or transformation. In this dissertation, various aspects of the operation of a microbially-active carbon-based advanced treatment train producing water intended for potable reuse are examined, including fate of dissolved organic carbon, underlying microbial populations, and functional genes are explored. Further, dynamics associated with antibiotic resistance genes (ARGs), identified as a microbially-relevant CECs, are also assessed. Overall, this dissertation advances understanding associated with the interplay between and within treatment processes as they relate to removal of various organic carbon fractions, microbially community dynamics, functional genes, and ARGs. Further, when relevant, these insights are contextualized to operational conditions, process upsets, water quality parameters, and other intended water uses within the water industry with the goal of broadening the application of advanced molecular tools beyond the scope of academic research. Specifically, this dissertation illuminates relationships among organic carbon fractions and molecular markers within an advanced treatment train employing flocculation, coagulation, and sedimentation (FlocSed), ozonation, biologically active carbon (BAC) filtration, granular active carbon (GAC) contacting, and UV disinfection. Biodegradable dissolved organic carbon (BDOC) analysis was adapted specifically as an assay relevant to assessing dissolved organic carbon biodegradability by BAC/GAC-biofilms and applied to profile biodegradable/non-biodegradable organic carbon as wastewater effluent passed through each of these treatment stages. Of particular interest was the role of ozonation in producing bioavailable organic carbon that can be effectively removed by BAC filtration. In addition to understanding the removal of fractionalized organic carbon, next generation DNA sequencing technologies (NGS) were utilized to better understand the microbial dynamics characteristic of complex microbial communities during disinfection and biological treatment. Specifically, this analysis was focused on succession and colonization of taxa, genes related to a wide range of functional interests (e.g. metabolic processes, horizontal gene transfer, DNA repair, and nitrogen cycling), and microbial CECs. Finally, NGS technologies were employed to assess the differences between a wide range of water use categories, including conventional drinking water, potable reuse, and non-potable reuse effluent's microbiomes to identify core and discriminatory taxa associated with intended water usage. The outcomes of this dissertation provide valuable information for optimizing carbon-based treatment trains as an alternative to membrane-based treatment for sustainable water reuse and also advance the application of NGS as a diagnostic tool for assessing the efficacy of various water treatment technologies for achieving treatment goals. / Doctor of Philosophy / Several factors have led to increased stress on conventional drinking water sources and widespread global water scarcity. Projections indicate that continued population growth, increased water demand, and degradation of current freshwater resources will negatively contribute to water needs and underscore the need to secure new potable (i.e. fit for human consumption) sources. Water reuse is a promising alternative to offset the growing demands on traditional potable sources and ameliorate negative consequences associated with water scarcity. Discharge of treated wastewater to marine environments is especially a lost opportunity, as the water will no longer be of value to freshwater habitats or as a drinking water source. Water reuse challenges the conventional wastewater treatment paradigm by providing advanced treatment of wastewater effluent to produce a valuable resource that can be safely used directly for either non-potable (e.g., irrigation, firefighting) or potable (i.e., drinking water) applications. The means of achieving advanced treatment of wastewater effluents can take many forms, commonly relying on the utilization of membrane filtration. However, membrane filtration is an intensive process and suffers from high initial costs, high operational costs, membrane fouling with time, and the production of a salty and difficult to dispose of waste stream. These drawbacks have motivated the water reuse industry to explore more sustainable approaches to achieving high quality effluents. One such alternative relies on the utilization of microorganisms to provide biological degradation and transformation of contaminants through a process known as biologically active filtration (BAF). Comparatively to membrane systems, BAF is more cost effective and produces significantly fewer byproducts while still producing high quality treated water for reuse. However, the range in quality of the resulting treated water has not yet been fully established, in part due to the lack of understanding of the complex microbial communities responsible for biological treatment. As water and wastewater treatment technologies have evolved over the past century, many biological treatments have remained largely 'black box' due to the lack of effective tools to identify the tens of thousands of species of microbes that inhabit a typical system and to track their dynamics with time. Instead, analysis has largely focused on basic water quality indicators. This dissertation takes important steps in advancing the implementation of the study of DNA and biodegradable organic carbon (BDOC) analysis to improve understanding of the mechanisms that drive different water reuse treatment technologies and to identify potential vulnerabilities. Insights gained through application of these tools are contextualized to observed operational conditions, process upsets, and water quality measurements. This helped to advance the use of DNA-based tools to better inform water treatment engineering practice. Specifically, this dissertation dives into the relationships between organic carbon and DNA-based markers within an advanced treatment train employing flocculation, coagulation, and sedimentation (FlocSed), ozonation, biologically active carbon (BAC) filtration, granular active carbon (GAC) contacting, and UV disinfection. Development and application of the BDOC test revealed that the bulk of organic carbon entering the treatment train is dissolved. Further, BDOC analysis served to characterize the impact of specific treatment processes and changes in operational conditions on both biodegradable and non-biodegradable organic carbon fractions. Such information can help to inform continued process optimization. Utilization of DNA-based technologies shed light on the functional capacity of microbial communities present within each stage of treatment and the fate of antibiotic resistance genes (ARGs). ARGs are of concern because, when present in human pathogens, they can result in the failure of antibiotics to cure deadly infections. Other functional genes of interest were also examined using the DNA-based analysis, including genes driving metabolic processes and nitrogen cycling that are critical to water purification during BAF treatment. Also, the DNA-based analyses made it possible to better understand the effects of disinfectants on microbes. Interestingly, some ARG types increased in relative abundance (a measure analogous to percent composition) response to treatments, such as disinfection, and others decreased. Characterization of the microbial communities and their dynamic response to changing operation conditions were also observed. For example, it was possible to characterize how the profiles of microbes changed with time, an ecological process called succession, during BAC filtration and GAC contacting. Generally, this analysis, coupled with the functional analysis, shed light on the important, divergent roles of bacterial communities on organic degradation during both BAC and GAC treatment. Finally, a study was conducted that compared the microbiome (i.e. entire microbial community) between a wide range of conventional drinking water, potable reuse water, and non-potable reuse waters. Here it was found that significant differences existed between the microbial communities of water intended for potable or non-potable usage. This work also looked to expand the application of NGS technologies beyond strictly academic research by developing the application of more advanced DNA-based tools for treatment train assessment and monitoring. potable reuse water reuse next generation sequencing antibiotic resistance functional metagenomic analysis microbial ecology advanced water treatment biodegradable dissolved organic carbon
506	Life cycle assessment of the unbleached bamboo sanitary pad : A case study performed at Hempur Mirzaie, Azita January 2021 (has links) Women's most common menstrual product is sanitary pads. Most disposable sanitary pads are constructed of up to 90% non-biodegradable plastics and bleached wood pulp. Throughout the sanitary pad's life cycle, there is a risk of exposure to toxic emissions harmful to humans and ecosystems. In contrast, disposable sanitary pads' health and environmental consequences have received little attention due to cultural stigma associated with menstruation and a lack of information regarding the chemical components used in sanitary pads. A case study has been performed at the Hempur company in Stockholm, Sweden, to evaluate potential environmental impacts of a sanitary disposal pad made almost entirely of unbleached bamboo pulp and polylactic plastic (PLA). The study's objectives were accomplished using a comparative life cycle assessment methodology to identify potential trade-offs between Hempur disposable sanitary pads and a conventional disposable sanitary pad consisting of non-biodegradable polymers and bleached wood pulp. Thus, understanding the study's results allows the implementation of recommendations to improve the environmental performance of Hempur sanitary pads. The study results indicate that Hempur plant-based sanitary pads, even though shipped to Sweden from China, have lower adverse environmental impacts —on average 40% less than conventional sanitary pads created using traditional materials and manufacturing sites in European countries. More than 80% of the overall impacts of the conventional sanitary pad were attributed to bleached wood pulp and low-density polyethylene. The upstream operations of Hempur sanitary pads were identified as the least environmentally friendly phase of the product due to the use of unbleached wood pulp and polylactic plastic, which together account for between 40% and 80% of all impact categories, most notably water scarcity and abiotic element depletion. Other factors and assumptions identified during the sensitivity analysis suggested the potential for reducing the environmental footprint of Hempur sanitary pads. By transitioning from coal to hydropower to generate electricity for bamboo pulp manufacturing, Hempur's upstream operations will dramatically improve their environmental performance, resulting in a reduction in global warming and acidification. Finally, this study suggests that other alternatives for PLA and use bamboo in the core part of Hempur sanitary pad should be considered and assessed. In this study, however, parts of the life cycle inventory process were omitted due to a lack of data on the materials and process method, which may affect the precision of the results. Life cycle assessment Disposal sanitary pads Bamboo plant Polylactic plastic (PLA) non- biodegradable plastics Bleached wood pulp Eco-friendly materials Engineering and Technology Teknik och teknologier
507	An Assessment of Novel Biodegradable Magnesium Alloys for Endovascular Biomaterial Applications Persaud-Sharma, Dharam 10 June 2013 (has links) Magnesium alloys have been widely explored as potential biomaterials, but several limitations to using these materials have prevented their widespread use, such as uncontrollable degradation kinetics which alter their mechanical properties. In an attempt to further the applicability of magnesium and its alloys for biomedical purposes, two novel magnesium alloys Mg-Zn-Cu and Mg-Zn-Se were developed with the expectation of improving upon the unfavorable qualities shown by similar magnesium based materials that have previously been explored. The overall performance of these novel magnesium alloys has been assessesed in three distinct phases of research: 1) analysing the mechanical properties of the as-cast magnesium alloys, 2) evaluating the biocompatibility of the as-cast magnesium alloys through the use of in-vitro cellular studies, and 3) profiling the degradation kinetics of the as-cast magnesium alloys through the use of electrochemical potentiodynamic polarization techqnique as well as gravimetric weight-loss methods. As compared to currently available shape memory alloys and degradable as-cast alloys, these experimental alloys possess superior as-cast mechanical properties with elongation at failure values of 12% and 13% for the Mg-Zn-Se and Mg-Zn-Se alloys, respectively. This is substantially higher than other as-cast magnesium alloys that have elongation at failure values that range from 7-10%. Biocompatibility tests revealed that both the Mg-Zn-Se and Mg-Zn-Cu alloys exhibit low cytotoxicity levels which are suitable for biomaterial applications. Gravimetric and electrochemical testing was indicative of the weight loss and initial corrosion behavior of the alloys once immersed within a simulated body fluid. The development of these novel as-cast magnesium alloys provide an advancement to the field of degradable metallic materials, while experimental results indicate their potential as cost-effective medical devices. Magnesium Alloys Biodegradable Stents Corrosion Corrosion Science Mg-Zn-Cu Mg-Zn-Se Mg-Zn Biocompatibility Mechanical Properties Absorption Multi-Vitamin Effect Tissue Growth Magnesium Corrosion Control Magnesium Stents Biodegradable Stents Cardiovascular Endovascular Medical Devices Medical Device Minimally Invasive Endovascular Device Dharam Persaud Dharam Persaud-Sharma Biomaterials Biomedical Devices and Instrumentation Equipment and Supplies Surgical Procedures, Operative Therapeutics
508	Formulations et modifications par extrusion réactive d'un mélange de polymères biodégradable et partiellement biosourcé / Formulations and modifications by reactive extrusion of partially biosourced blend of biodegradable polymers Deleage, Fanny 19 July 2016 (has links) Dans le domaine des plastiques biodégradables, les produits se doivent d’être de plus en plus compétitifs. Ces travaux, menés entre le laboratoire IMP@UJM et la société LCI ont eu pour objectif principal l’augmentation de la part en matières d’origines renouvelables dans le mélange de polymères biodégradable poly(butylène adipate-co-téréphtalate) (PBAT)/TPF (farine thermoplastique), sans diminuer ses propriétés mécaniques. Ce mélange est obtenu par extrusion en une seule étape, comprenant la plastification de la farine et le mélange avec le polyester. L’enjeu scientifique était donc en premier lieu de comprendre les relations entre la mise en oeuvre, l’établissement de la morphologie du mélange, la concentration en chacun des polymères et les propriétés mécaniques. Dans un second temps, ces résultats ont été exploités en vue de l’augmentation des propriétés mécaniques du mélange. L’influence de la concentration en TPF et du rapport de viscosité entre les phases a donc été mise en évidence sur toute la gamme de concentration, mettant en lumière l’importance de contrôler la tension interfaciale du mélange. Des mécanismes d’établissement de la morphologie et des interprétations quant à son effet sur les propriétés mécaniques du mélange sont proposés. L’étude d’une modification par extrusion réactive du PBAT est ensuite présentée. L’évolution de la structure du polyester est caractérisée par chromatographie d’exclusion stérique en fonction de différents paramètres, dont le temps de mélange. Enfin, différentes modifications du mélange PBAT/TPF sont testées. L’influence de la modification du PBAT, de la modification de la phase TPF ou de la modification de l’interface via des agents compatibilisants est étudiée sur les propriétés rhéologiques, morphologiques et mécaniques du mélange / Biodegradable plastics need to be more and more competitive. This work, conducted between IMP@UJM laboratory and LCI company had the main objective of increasing the content of renewable materials in the biodegradable blend of poly(butylene adipate-co-terephthalate) (PBAT)/ thermoplastic flour (TPF), without decreasing its mechanical properties. The blend was obtained by a single step extrusion, including flour thermoplastification and blending with the polyester. The scientific challenge was to understand the relationship between processing parameters, the morphology establishment, the concentration of each phase of the blend and its mechanical properties. Then, these results were exploited in order to increase the mechanical properties of the mixture. The influence of the concentration of TPF and the viscosity ratio between the phases was highlighted over the entire concentration range. This highlighted the importance of controlling the interfacial tension of the blend. Mechanisms of the morphology establishment were proposed, as well as interpretations about its effect on the mechanical properties of the blend. Then, a study of the PBAT modification by reactive extrusion was proposed. The evolution of the polyester structure was characterized by size exclusion chromatography, according to various parameters including the mixing time. Finally, various modifications of PBAT/TPF mixture were tested. Modifying the PBAT, the TPF phase or the interface via the compatibilizers were studied in order to tailor the rheological, morphological and mechanical properties Polyester biodégradable Farine de maïs thermoplastique Amidon thermoplastique Biodégradable Mélange de polymères immiscibles Morphologie Propriétés rhéologiques Propriétés mécaniques Relations structure-propriétés Compatibilisation Extrusion réactive Biodegradable polyester Thermoplastic corn flour Thermoplastic starch Biodegradable Immiscible polymer blends Morphology Rheological properties Mechanical properties Structure-property relationships Compatibilisation Reactive extrusion
509	Designing immobilized catalysts for chemical transformations: new platforms to tune the accessibility of active sites Long, Wei 03 July 2012 (has links) Chemical catalysts are divided into two traditional categories: homogeneous and heterogeneous catalysts. Although homogeneous (molecular) catalysts tend to have high activity and selectivity, their wide application is hampered by the difficulties in catalyst separation. In contrast, the vast majority of industrial scale catalysts are heterogeneous catalysts based on solid materials. Immobilized catalysts, combining the advantages of homogeneous and heterogeneous catalysts, have developed into an important field in catalysis research. This dissertation presents synthesis, characterization and evaluation of several novel immobilized catalysts. In the first part, MNP supported aluminum isoproxide was developed for ROP of Є-caprolactone to achieve facile magnetic separation of catalysts from polymerization system and reduce toxic metal residues in the poly(caprolactone) product. Chapter 3 presents a silica coated MNP supported DMAP catalyst that was synthesized and displayed good activity and regio-selectivity in epoxide ring opening reactions. In Chapter 4, hybrid sulfonic acid catalysts based on polymer brush materials have been developed. The unique polymer brush architecture permits high catalyst loadings as well as easy accessibility of the active sites to be achieved in this catalytic system. In Chapter 5, aminopolymer-silica composite supported Pd catalysts with good activity and selectivity were developed for the selective hydrogenation of alkynes. In this case, the aminopolymer composite works as a stabilizer for palladium nanoparticles, as well as a modifier to tune the catalyst selectivity. All in all, the general theme of the thesis is developing new immobilized catalysts with improved activity/selectivity as well as easy separation via rational catalyst design. Alkyne Ring-opening polymerization Palladium Selective hydrogenation Polymerbrush Atom-transfer radical polymerization Magnetic nanoparticle Immobilized catalyst Catalysis Biodegradable polymer Solid acid Aminopolymer-silica composite Epoxide ring-opening Catalysts Synthesis
510	Lengvai biologiškai skaidomų organinių teršalų koncentracijos Palangos ir Visagino miestų nuotekose tyrimai / Investigation Of Concentration Of Readily Biodegradable Organic Matter In Wastewater Of Palanga And Visaginas Baltrūnienė, Rima 18 July 2011 (has links) Šiame darbe yra aprašomi lengvai biologiškai skaidomų organinių teršalų koncentracijos Palangos miesto nuotekose atskirais metų laikotarpiais bei Visagino miesto nuotekose tyrimai. Tyrimams nuotekos buvo imamos prieš biologinį valymą, o veiklusis dumblas – iš veikliojo dumblo reaktoriaus pabaigos. Tyrimai atlikti VGTU Vandentvarkos katedros ir UAB „Palangos vandenys“ laboratorijose. Siekiant įvertinti teršalų bei technologinių parametrų kitimą bei jų įtaką nuotekų išvalymo rodikliams, buvo surinkti ir statistiškai apdoroti Palangos ir Visagino nuotekų tyrimų rodikliai. Analizuota nuotekų parametrų priklausomybė, teršalų koncentracijų kaita, nuotekų valymo efektyvumas ir jų įtaka biologiniam fosforo šalinimui. Ištirtos lengvai biologiškai skaidomų organinių teršalų koncentracijos. Gauti rezultatai palyginti su anksčiau VGTU Vandentvarkos katedroje atliktų magistrantų nuotekų tyrimų rezultatais. / It is the investigations for determination of concentration of easily biodegradable organic matter in wastewater of Palanga and Visaginas towns. Wastewater for investigations have been taken before biological treatment, and active sludge - from the end of active sludge reactor. The investigations were carried out at Water Management Department of Vilnius Gediminas Technical University and UAB "Palangos vandenys" laboratories. The indicators of investigations of Palanga and Visaginas wastewater were collected and statistically processed in order to evaluate alteration of technological parameters and their influence to indicators of wastewater cleaning. It was analysed the relationship between various parameters in order to find out their influence for the efficiency of biological phosphorus removal. It was studied easily biodegradable organic pollutant concentrations too. The results are compared with previously results of investigations, made by postgraduates of Water Management Department of Vilnius Gediminas Technical University. Biologinis fosforo šalinimas Lengvai biologiškai skaidoma ChDS dalis Veiklusis dumblas Biological phosphorus removal Readily biodegradable organic matter Influent COD fractions Activated sludge

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