Obtenção de fibras de La0,6Sr0,4Co1-yFeyO3 pela técnica de electrospinning e sua caracterização para aplicação como cátodo em células a combustível

Lubini, Marcieli

January 2016

Neste trabalho, investigou-se a obtenção de fibras de La0,6Sr0,4Co1-yFeyO3 pela técnica de electrospinning e sua caracterização visando a sua aplicação como cátodo em células a combustível de óxido sólido de temperatura intermediária (SOFC-IT). Foram obtidos 5 compostos perovskitas LaxSr1-xCo1-yFeyO3 (LSCF) variando-se a quantidade de cobalto na composição (La0,6Sr0,4Co1-yFeyO3, sendo y = 1,0; 0,8; 0,6; 0,4; 0,2). As fibras LSCF, após tratamento térmico de 1000 ºC, apresentaram diâmetro médio em torno de 1 μm e estrutura perovskita com simetria romboédrica, com exceção do composto La0,6Sr0,4FeO3, que apresentou estrutura ortorrômbica. Foram avaliadas as propriedades elétricas das fibras sem compactação, compactada e sinterizada no intervalo de temperatura de 25-900 ºC. A condutividade elétrica das fibras LSCF aumentou com a compactação e sinterização das fibras e com o aumento do conteúdo de cobalto. As fibras sem compactação apresentaram valores de condutividade elétrica entre 0,23 S.cm-1 para La0,6Sr0,4FeO3 (LSF) à 0,43 S.cm-1 para La0,6Sr0,4Co0,8Fe0,2O3 (LSCF82) a 600 °C. Nas fibras compactadas os valores de condutividade elétrica aumentaram de 0,90 S.cm-1 para LSF à 9,06 S.cm-1 para LSCF82 a 600 °C. As fibras sinterizadas apresentaram os maiores valores de condutividade elétrica, 71 S.cm-1 para LSF e 832 S.cm-1 para LSCF82 em 600 ºC. A avaliação do desempenho eletroquímico das fibras LSCF como cátodo foi estudada por espectroscopia de impedância em células simétricas, contendo o eletrólito de céria dopada com gadolínio (CGO) e cátodos LSCF infiltrados com CGO. As medidas de impedância mostraram que os diagramas de Nyquist são compostos de dois a três semicírculos, dependendo da temperatura da medida. Os cátodos LSCF com maior conteúdo de cobalto apresentaram menor resistência de polarização. O cátodo La0,6Sr0,4Co0,8Fe0,2O3 apresentou a menor resistência de polarização entre 500 e 900 °C, classificando este cátodo compósito como um promissor material para SOFC de temperatura intermediária baseado em eletrólito CGO. / In this work, the preparation of La0.6Sr0.4Co1-yFeyO3 fibers by electrospinning and its characterization was investigated aiming the production of cathodes for Intermediate Temperature Solid Oxide Fuel Cell (SOFC-IT). Five compounds of the family LaxSr1-xCo1-yFeyO3 (LSCF) were obtained varying the cobalt content (La0.6Sr0.4Co1-yFeyO3, where y = 1.0; 0.8; 0.6; 0.4; 0.2). The electrospun La0.6Sr0.4Co1-yFeyO3 (y=0.2-1.0) fibers resulted in an average diameter of about 1 μm and perovskite crystalline structure with rhombohedral symmetry after heat treatment at 1000 °C, except for La0.6Sr0.4FeO3 that crystallized in an orthorhombic structure. The electrical properties of the fibers in the non-compacted, compacted and sintered forms were investigated in the temperature range of 25-900 °C. The electrical conductivity of LSCF fibers increases with the compaction and sintering of the fibers and with the increase of cobalt content. The non-compacted fibers showed electrical conductivities ranging from 0.23 S.cm-1 for La0.6Sr0.4FeO3 (LSF) up to 0.43 S.cm-1 for La0.6Sr0.4Co0.8Fe0.2O3 (LSCF82) at 600 °C. The electrical conductivity increased in compacted fiber samples to 0.90 S.cm-1 for LSF and to 9.06 S.cm-1 for LSCF82 at 600 °C. The sintered fibers showed the highest electrical conductivity for all samples, 71 S.cm-1 for LSF and 832 S.cm-1 for LSCF82 at 600 ºC. The electrochemical performance of LSCF fibers as cathode was studied by impedance spectroscopy in symmetrical cells containing gadolinium doped ceria (CGO) electrolyte and LSCF cathode infiltrated with CGO. Impedance measurements showed that the Nyquist diagrams have two or three semicircles, depending on the measurement temperature. The LSCF cathodes with higher cobalt content exhibit lower polarization resistance and the La0.6Sr0.4Co0.8Fe0.2O3 cathode had the lowest polarization resistance between 500 and 900 °C, classifying this composite cathode as a promising material for intermediate temperature SOFC based on CGO electrolyte.

Células a combustível

Eletrofiação

Fibras cerâmicas

Propriedades elétricas

La0.6Sr0.4Co1-yFeyO3 fibers

Electrospinning

Microestructure

Cathode

Fuel cells

Modificação química do poli(3-hidroxibutirato) e preparação de membranas por eletrofiação para aplicação em biomateriais. / Poly(3-hydroxybutyrate) chemical modification and fiber mats preparation by electrospinning for biomedical applications.

Sakaguti, Katia Yabunaka

08 November 2018

Devido ao crescente interesse em polímeros biodegradáveis, muitos estudos têm sido realizados a fim de se obter polímeros biodegradáveis com melhores propriedades mecânicas e de processamento. O poli(3-hidroxibutirato) (PHB) tem sido apresentado como um substituto para polímeros não-biodegradáveis em aplicações comerciais. Porém, sua elevada cristalinidade, instabilidade térmica e alto custo de produção são problemas que dificultam sua comercialização. Uma alternativa para modificá-lo e melhorar suas propriedades mecânicas é através de reações de transesterificação com poli(?-caprolactona) (PCL), um poliéster sintético, também biodegradável e com alto potencial para uso como biomaterial. Neste trabalho, realizou-se a extrusão reativa de blendas de PHB e PCL e o copolímero obtido foi caracterizado por ensaios de solubilidade, calorimetria exploratória diferencial (DSC), espectroscopia no infravermelho por transformada de Fourier (FTIR), espectrometria de ressonância magnética nuclear de hidrogênio (RNM-1H) e de carbono (RNM-13C). Os resultados indicaram que houve modificação do PHB resultando no copolímero PHB-co-PCL, que apresentou menor cristalinidade que os homopolímeros de partida. Com o PHB-co-PCL, foram feitas medidas de viscosidade e ensaios de eletrofiação, variando-se os parâmetros do processo e da solução. As análises por microscopia eletrônica de varredura (MEV) apontaram formação de fibras lisas e uniformes com diâmetros médios entre 900 a 1200 nm. Análise de viabilidade celular confirmou que o material não é citotóxico, favorecendo sua aplicabilidade em mantas porosas na engenharia de tecidos. / Due to the increasing interest in biodegradable polymers, many studies have been conducted in order to obtain biodegradable polymers with improved mechanical and processing properties. The poly(3-hydroxybutyrate) (PHB) has been proposed as an ideal substitute for non-biodegradable polymers in commercial applications. However, its high crystallinity, thermal instability and high production costs are problems that have limited its commercialization. An alternative to modify it and improve its mechanical properties is through transesterification reactions with poly(?-caprolactone) (PCL), a synthetic polyester, also biodegradable and with high potential for use as a biomaterial. In this work, reactive extrusion of PHB/PCL blend was carried out, and the copolymer was characterized by solubility tests, differential scanning calorimetry (DSC), Fourier transform infrared spectroscopy (FTIR), hydrogen (1H-NMR) and carbon (13C-NMR) nuclear magnetic resonance spectroscopies. The results indicated that PHB was modified, resulting in the copolymer PHB-co-PCL, showing lower crystallinity than the homopolymers. Viscosity measurements of PHB-co-PCL solutions were performed and electrospinning tests were carried out under different conditions. The scanning electron microscopy analysis (SEM) indicated the formation of smooth and uniform fibers, with average diameter between 900-1200 nm. Cell viability analysis confirmed that the material is not cytotoxic, favoring its applicability for the production of porous fiber mats in tissue engineering.

Biodegradable polymers

Biomateriais

Biomaterials

Electrospinning

Eletrofiação

PHB-co-PCL

Polímeros (Materiais)

Gás ozônio como agente esterilizante de nanofibras eletrofiadas para engenharia tecidual: avaliação da segurança e da eficácia / Ozone gas as sterilant for electrospun nanofibers for tissue engineering: safety and efficacy evaluation.

Rediguieri, Carolina Fracalossi

11 October 2016

Com o aumento da expectativa de vida e o envelhecimento da população, a medicina regenerativa vem ocupando um importante espaço visando manter a qualidade de vida da população. A engenharia de tecidos, apoiada nos avanços da biotecnologia e da nanotecnologia, vem se configurando como alternativa mais versátil e menos custosa ao reparo e transplante de tecidos e órgãos. Os arcabouços para engenharia tecidual constituídos de nanofibras têm o potencial para mimetizar a arquitetura nanométrica dos tecidos humanos, especialmente devido à grande área superficial e elevada porosidade. Para a fabricação de arcabouços de nanofibras, a técnica mais utilizada é a de eletrofiação, devido à sua alta versatilidade, e os materiais mais estudados são os polímeros biodegradáveis e biocompatíveis, que são os mais desejados para fins biomédicos. A esterilização é uma etapa crítica no processo de fabricação de produto médico implantável e pode ter impacto no desempenho dos arcabouços poliméricos. Desta forma, o objetivo deste estudo foi avaliar o impacto da esterilização por gás ozônio em arcabouços de nanofibras poliméricas eletrofiadas para engenharia de tecidos. A esterilização por ozônio foi eficaz na inativação do indicador biológico G. stearothermophilus, caracterizando eficácia na letalidade microbiana; igualmente, não se detectou crescimento microbiano no teste de esterilidade. Os arcabouços de nanofibras de poli(ácido láctico-co-ácido glicólico) tiveram suas propriedades físico-químicas, mecânicas e biológicas preservadas, mantendo o mesmo desempenho como suporte para o crescimento de fibroblastos NIH3T3 após a esterilização. Já os arcabouços de poli-caprolactona, tiveram suas propriedades alteradas e apresentaram um melhor desempenho na proliferação celular de fibroblastos L929 após a esterilização. Assim, o gás ozônio se mostrou como um método alternativo para a esterilização de nanofibras poliméricas para engenharia tecidual. / Since world population is ageing, regenerative medicine has become a growing area in the medical field in order to maintain the life quality of population. With the advance of biotechnology and nanotechnology, tissue engineering has emerged as a more versatile and less costly alternative to tissue repair and transplantation. Nanofibers have the potential to mimic the human tissue architecture at the nanometer scale, especially due to their large surface area and high porosity. Electrospinning is the most applied technique to fabricate nanofibers scaffolds mainly because of its powerful and high versatility. Many polymers can be used on the fabrication of nanofibers scaffolds; however, the biodegradable and biocompatible polymers are the most desired ones for biomedical purposes. Sterilization is a critical step in the fabrication process and might impact the performance of polymeric scaffolds. Therefore, the aim of this study was to evaluate the impact of sterilization by ozone gas on polymeric electrospun nanofibers scaffolds for tissue engineering. Ozone gas sterilization was efficient in killing the G. stearothermophilus spores, a common biological indicator used for validation of sterilization processes. The sterilization method preserved the physico-chemical, mechanical, and biological properties of poly(lactic-co-glycolic) acid nanofibers, keeping the performance of NIH3T3 proliferation on the scaffolds. On the other hand, the same sterilization method altered some properties of poly-caprolactone electrospun scaffolds, what improved L929 fibroblasts proliferation on the scaffolds after sterilization. Therefore, ozone gas was found to be a benign sterilization method for polymeric electrospun scaffolds for tissue engineering.

Biocompatibilidade

Biocompatibility

Electrospinning

Eletrofiação

Engenharia de tecidos

Esterilização

Nanofibers

Nanofibras

Nanotechnology

Nanotecnologia

Sterilization

Tissue engineering

O papel da concentração de nanofibras e da composição da matriz resinosa nas propriedades flexurais de compósitos experimentais baseados em nanofibras / Flexural properties of experimental nanofiber reinforced composite are affected by resin composition and nanofiber/resin ratio

Vidotti, Hugo Alberto

09 November 2015

O objetivo do presente estudo foi de avaliar a influência de soluções de resina com diferentes proporções de monômeros e diferentes concentrações em massa de nanofibras nas propriedades flexurais de compósitos resinosos experimentais reforçados com nanofibras de poliacrilonitrila (PAN). Materiais e métodos: Nanofibras de PAN foram produzidas pelo processo de eletrofiação e caraterizadas por teste de tração e microscopia eletrônica de varredura (MEV). Os compósitos experimentais foram produzidos pela infiltração das mantas de nanofibras com diferentes misturas de BisGMA-TEGDMA (BisGMA/TEGDMA: proporções em % massa de 30/70, 50/50, e 70/30). Foram incorporadas diferentes concentrações em massa de nanofibras (de 0% a 8%). Espécimes em forma de barra foram seccionados a partir de blocos do compósito experimental e armazenados em água na temperatura de 37oC por 24h anteriormente à realização dos testes de flexão de três pontos. Foram avaliados a resistência flexural (RF), o módulo flexural (MF) e o trabalho de fratura (TF). Resultados: Os testes de tração das nanofibras de PAN demonstraram um comportamento anisotrópico das mantas de nanofibras. As propriedades mecânicas exibiram maiores valores na direção perpendicular ao eixo de rotação do coletor metálico utilizado na produção das fibras por eletrofiação. Maiores proporções de BisGMA nas misturas de resina resultaram em maiores valores de RF e MF, o que não ocorreu para os valores de TF. A adição de diferentes concentrações de nanofibras não afetou as propriedades de RF e MF em comparação com o grupo controle (resina pura) (p>0.05). No entanto, a adição das nanofibras promoveu um aumento significante do TF, principalmente para as misturas de resina com maior proporção de TEGDMA (p<0,05). Significância: A inclusão de nanofibras de PAN em resinas de modo a formar compósitos resinosos reforçados por nanofibras não afetou negativamente as propriedades flexurais do material e resultou em um aumento significativo da tenacidade, uma propriedade desejável para um material a ser utilizado para aplicação restauradora. / The present study had the objectives to evaluate the influence of different resin blends concentrations and nanofibers mass ratio on flexural properties of experimental Poliacrylonitrile (PAN) nanofibers reinforced composite. Materials and Methods: Poliacrylonitrile (PAN) nanofibers mats were produced by electrospinning and characterized by tensile testing and scanning electron microscopy (SEM). Experimental resin-fiber composite beams were manufactured by infiltrating PAN nanofiber meshs with varied concentrations of BisGMA-TEGDMA resin blends (BisGMA/TEGDMA: 30/70, 50/50 and 70/30 weight %). The mass ratio of fiber to resin varied from 0% to 8%. Beams were cured and stored in water at 37oC. Flexural strength (FS), flexural modulus (FM) and work of fracture (WF) were evaluated by three-point bending test after 24 hs storage. Results: The tensile properties of the PAN nanofibers indicated an anisotropic behavior being always higher when tested in a direction perpendicular to the rotation of the collector drum. Except for WF, the other flexural properties (FS and FM) were always higher as the ratio of BisGMA to TEGDMA increased in the neat resin beams. The addition of different ratios of PAN fibers did not affect FS and FM of the composite beams as compared to neat resin beams (p>0.05). However, the addition of fibers significantly increased the WF of the composite beams, and this was more evident for the blends with higher TEGDMA ratios (p<0.05). Significance: The inclusion of PAN nanofibers into resin blends did not negatively affect the properties of the composite and resulted in an increase in toughness that is a desirable property for a candidate material for restorative application.

Electrospinning

Eletrofiação

Flexural properties

Nanofibers

Nanofibras

Poliacrilonitrila

Polycrylonitrile

Propriedades flexurais

Resin composite

Resina composta

Etude et développement de structures fibreuses non-tissées résistantes à la pénétration bactérienne / Development of non-woven fibrous structures resistant to bacterial and/or viral penetration

Dessauw, Etienne

16 April 2019

Ces travaux ont pour objet l’élaboration de nouvelles structures poreuses non tissées antibactériennes. Différentes stratégies ont été développées : l’une a consisté à élaborer des mats poreux par electrospinning en utilisant un polymère biosourcé et biocompatible et l’autre voie consistait à modifier un support fibreux provenant d’un masque de protection respiratoire commercial. La méthode des assemblages par interactions ioniques en superposant de façon alternative les couches de polymères cationiques et les polymères anioniques à la surface du filtre médian en polypropylène (PP) a permis d’élaborer de nouvelles structures ayant de bonnes propriétés antioxydantes et antibactériennes. Le polymère anionique, dérivé du polymère de cyclodextrine présente l’avantage de pouvoir encapsuler un agent antimicrobien biosourcé, le carvacrol. Une autre approche a consisté à modifier des supports en PP avec de l'acide tannique, un polyphénol d'origine naturelle. Dans cette étude, deux stratégies ont été mises en place afin de fonctionnaliser le PP avec de l’acide tannique (AT). La première est l’extrusion réactive du PP avec l’AT en présence (ou non) de peroxyde de dicumyle (DCP) pour greffer directement l’acide tannique sur le PP. La deuxième stratégie consiste à polymériser l’AT au travers d’une couche poreuse de PP extraite d’un masque de protection commercial, afin de permettre l’immobilisation physique de l’AT à la surface du mat fibreux en PP. Le greffage en surface via un procédé “grafting from” a également été étudié. Ces matériaux ont montré de bonnes propriétés antiradicalaires. / The purpose of this work is to develop new antibacterial non-woven porous structures. Different strategies were developed: one was to develop porous structures by electrospinning using a biosourced and biocompatible polymer, the other was to modify a fibrous support from a commercial respiratory protection mask. Assembling materials using ionic interactions by alternatively superposing cationic polymer layers and anionic polymers on the surface of the polypropylene (PP) median filter allowed to develop new structures with good antioxidant and antibacterial properties. The anionic polymer, derived from the cyclodextrin polymer, has the advantage of being able to encapsulate a bio-based antimicrobial agent, carvacrol. Another approach was to modify PP filters with tannic acid, a naturally occurring polyphenol. In this study, two strategies were implemented to functionalize PP with tannic acid (TA). The first is the reactive extrusion of PP with TA in the presence (or not) of dicumyl peroxide (DCP) to directly graft tannic acid onto PP. The second strategy consists in polymerizing the TA through a porous layer of PP extracted from a commercial mask, in order to allow the physical immobilization of the TA on the surface of the PP fibrous mat. Surface grafting using a "grafting from" process was also studied. These materials have shown good anti-free radical properties.

Electrofilage

Mâts fibreux

Fonctionnalisation

Polyesters biosourcés

Propriétés antibactériennes

Electrospinning

Fibrous scaffolds

Functionalization

Biopolyesters

Antibacterial properties

Development of electrospun nanofiber composites for point-of-use water treatment

Peter, Katherine T.

01 December 2016

A range of chemical pollutants now contaminate drinking water sources and present a public health concern, including organic compounds, such as pharmaceuticals and pesticides, and both metalloids and heavy metals, such as arsenic and lead. Metalloids and heavy metals have been detected in private drinking water wells, which do not fall under federal drinking water regulations, as well as in urban tap water, due to the introduction of contamination to the drinking water distribution system. Further, many so-called “emerging organic contaminants,” which are present in drinking water sources at detectable levels but have unknown long-term health implications, do not fall under federal drinking water regulations. To protect the health of consumers, drinking water treatment at the point-of-use (POU) (i.e., the tap) is essential. Next-generation POU treatment technologies must require minimal energy inputs, be simple enough to permit broad application among different users, and be easily adaptable for removal of a wide range of pollutants. Nanomaterials, such as carbon nanotubes and iron oxide nanoparticles, are ideal candidates for next-generation drinking water treatment, as they exhibit unique, high reactivity and necessitate small treatment units. However, concerns regarding water pressure requirements and nanomaterial release into the treated supply limit their application in traditional reactor designs. To bridge the gap between potential and practical application of nanomaterials, this study utilizes electrospinning to fabricate composite nanofiber filters that effectively deploy nanomaterials in drinking water treatment. In electrospinning, a high voltage draws a polymer precursor solution (which can contain nanomaterial additives, in the case of nanocomposites) from a needle to deposit a non-woven nanofiber filter on a collector surface. Using electrospinning, we develop an optimized, macroporous carbon nanotube-carbon nanofiber composite that utilizes the sorption capacity of embedded carbon nanotubes, and achieves a key balance between material strength and reactivity towards organic pollutants. Additionally, via single-pot syntheses, we develop two optimized polymer-iron oxide composites for removal of heavy metal contamination by inclusion of iron oxide nanoparticles and either cationic or anionic surfactants in the electrospinning precursor solution. In hybrid materials that contain a well-retained quaternary ammonium surfactant (tetrabutylammonium bromide) and iron oxide nanoparticles, ion exchange sites and iron oxide sites are selective for chromate and arsenate removal, respectively. We demonstrated that a sulfonate surfactant, sodium dodecyl sulfate, acted as a removable porogen and an agent for surface segregation of iron oxide nanoparticles, thus enhancing composite performance for removal of lead, copper, and cadmium. Notably, nanoparticles embedded in composites exhibited comparable activity to freely dispersed nanoparticles. Collectively, the composites developed in this work represent a substantial advance towards the overlap of effective nanomaterial immobilization and utilization of nanomaterial reactivity. Outcomes of this work advance current knowledge of nanocomposite fabrication, and contribute to the responsible and effective deployment of nanomaterials in POU drinking water treatment.

electrospinning

heavy metals

nanocomposite

organic micropollutants

point-of-use

water treatment

Civil and Environmental Engineering

Development of chemically active metal oxide composite nanofiber filters for water treatment

Greenstein, Katherine E.

01 December 2016

Small drinking water systems, often financially and resource-limited, face unprecedented challenges due to the current diversity and ubiquity of water pollutants. Well-characterized inorganic legacy pollutants, including arsenic, copper, hexavalent chromium, and lead, remain persistent in drinking water systems. In addition, emerging organic contaminants, like endocrine disrupting compounds and pharmaceuticals, are largely uncharacterized but prevalent in the environment and water supplies, calling into question what levels of these relatively new contaminants are truly safe in drinking water. Point-of-use (POU) and point-of-entry (POE) water treatment devices, installed at a specific tap or at the water entry point to a single facility, respectively, are necessary to ensure safe drinking water in contexts where centralized water treatment is not available or cannot adapt to meet new regulatory standards. While existing POU and POE technologies, including reverse osmosis and packed bed media filters, are effective for removing contaminants, installation costs, energy demands, and spatial footprints of these systems can inhibit their implementation. There is a need for new POU and POE technologies that remove a diversity of water contaminants while maintaining a small application footprint. Nanotechnology, referring to technology using material with at least one dimension or feature less than 100 nm in length, is ideal for meeting this need in drinking water treatment. With high surface area-to-volume ratios, nano-enabled treatment technologies exhibit enhanced reactivity with less material, keeping overall footprint relatively small. Specifically, electrospinning, a process in which a polymer precursor solution is electrified to produce a cohesive sheet of nanofibers, can be used to easily synthesize chemically active nanofiber filters for water treatment applications. In this study, we develop electrospun nanofiber filters that harness nano-scaled hematite (Fe2O3) for sorption of inorganic contaminants (e.g., As, Pb) and nano-scaled titanium dioxide (TiO2) for use with ultraviolet (UV) and visible light as an advanced oxidation process (AOP) for removal of emerging organic contaminants (e.g., benzotriazole, carbamazepine, DEET). Most importantly, we strive to optimize both reactivity and material strength to develop cohesive, durable filtration platforms that overcome barriers to use of nanomaterials in water treatment (e.g., concerns over leaching of nanoparticles deployed as suspensions). Herein, we first demonstrate reactivity optimization of pure (though brittle) TiO2 nanofiber photocatalysts by noble metal catalyst (Au) surface loading. Additionally, we optimize polymer-Fe2O3 composite nanofibers for reactivity while maintaining material flexibility by coating the doped polymer with additional Fe2O3 surfaces available for metal/metalloid uptake. Finally, we apply reactivity optimization and strategies to maintain material strength in the development of carbon/TiO2 nanofiber composites used for (photo)chemical filtration of water containing emerging organic contaminants. Ultimately, we find that nanofiber composites exhibit substantial reactivity and structural integrity in water treatment platforms. Outcomes of this work contribute to making nanomaterials, which have been studied for decades but have yet to be commercially employed for water treatment, practical for chemically active water filtration.

Electrospinning

Hematite

Nanofibers

Point of use

Titanium dioxide

Water treatment

Civil and Environmental Engineering

Investigation of Opuntia ficus-indica Mucilage Nanofiber Membrane Filtration for Water Systems

Muppaneni, Rasudha

11 March 2015

This work investigates the fabrication, characterization and testing of Opuntia ficus-indica mucilage nanofibers to be utilized in water filtration systems. These mucilage nanofibers are formed using different polymers through a process called electrospinning. The polymers used to promote the formation of nanofibers are poly vinyl alcohol (PVA) and polystyrene (PS). The mucilage is a jelly like substance extracted from the pads of the cactus plant. It is a mixture of proteins, complex polysaccharides and monosaccharaides. It is an inexpensive, non-toxic, biodegradable and biocompatible material which is present in abundance. The mucilage extracted from the pads is mixed with acetic acid to form the mucilage solution. The mucilage solution is then mixed by volume with co-spinning polymers, PVA and PS. PVA is a synthetic polymer that is water-soluble, and this work considers two types of PVA differentiated based upon molecular weight, such as low molecular weight PVA and high molecular weight PVA. Polystyrene is a synthetic polymer extracted from a monomer styrene, and it is inexpensive, biodegradable, and abundant. The polystyrene, in its solid form, is further decomposed using a solvent called D-Limonene. D-Limonene is a biodegradable, non-toxic solvent formed from the citrus extract of orange peelings. The PVA and PS solutions are mixed in several different volume ratios with the mucilage solutions. These solutions were electrospun and consistent nanofibers were obtained using the low molecular weight PVA solutions and the polystyrene solutions. The fibers and polymeric solutions were characterized by scanning electron microscopy (SEM), contact angle measurements, viscosity, and FTIR. Resulting mucilage nanofiber membranes were characterized by atomic fluorescence spectrometry (AFS) filtration testing. In addition, a life cycle analysis using the SimaPro software was performed to understand the environmental impact of solutions used to fabricate the mucilage nanofiber membranes. Characterization results confirm the formation of PVA:mucilage and PS:mucilage nanofibers. Filtration testing of the nanofiber membranes indicates better performance with membranes formed by PS: mucilage solutions as compared to PVA: Mucilage solutions. Overall, this work has shown that natural materials, such as cactus mucilage, can be synthesized with polymeric solutions to form environmentally friendly water filters.

Arsenic

Cactus Mucilage

Electrospinning

Life Cycle Analysis

Polystyrene

Poly Vinyl Alcohol

Electrical and Computer Engineering

Fabrication and Characterization of Polycarbonate Polyurethane (PCPU) Nanofibers Impregnated with Nanofillers

Katakam, Hruday chand

12 March 2015

Polycarbonate polyurethane (PCPU) has been studied as a novel polymer impregnated with nanoparticles for improved mechanical, thermal and adhesion properties [4]. This study investigates the synthesis of polycarbonate polyurethane (PCPU) polymeric nanofiber membranes by the process of electrospinning. This study further examines all the parameters associated with electrospinning a novel PCPU polymeric solution impregnated with nanofillers, such as nanoparticles, to produce fiber membranes. Tetrahydrofuran (THF) and N, N dimethylformamide (DMF) are used as solvents to dissolve PCPU polymer. One percent (1%) of nanofillers like silver and silica nanoparticles are added to PCPU polymer solution to investigate the impact on polymer solution properties, which in turn affects the fiber formation. Process parameters are studied by evaluating the impact each parameter has on the fiber formation. PCPU polymer concentrations of three polymer solutions (PCPU, PCPU + 1% silver and PCPU + 1% silica) with the appropriate solvent mixture ratio are achieved to produce polymeric fiber membranes with minimal bead formation. Polymeric nanofiber membranes of PCPU, PCPU + 1% silver and PCPU + 1% silica are produced using THF/DMF: 70/30 (V/V) solvent mixture. The polymeric nanofiber membranes obtained are characterized by using a scanning electron microscopy, rotational viscometer, tensiometer, contact angle measurement device, fourier transform infrared spectroscopy (FTIR). A comparative life cycle assessment (LCA) is performed to evaluate environmental impacts associated with solvents in the process of producing PCPU polymeric nanofiber membranes. The LCA is completed to gauge the potential impacts PCPU nanofiber membranes may have when utilized for various applications. This study discusses the successful production and characterization of good quality (no beading) polymeric nanofiber membranes of PCPU and novel composites of PCPU + 1% silver and PCPU + 1% silica. This two dimensional production of impregnated PCPU in nanofiber form will give researchers the opportunity to capitalize on the large surface areas of PCPU nanofibers versus PCPU thin films.

Contact Angle

Electrospinning

Life Cycle Analysis

Surface Tension

Viscosity

Electrical and Computer Engineering

Nanotechnology Fabrication

Fabrication and Comparison of Electrospun Cobalt Oxide-Antimony Doped Tin Oxide (CoO-ATO) Nanofibers made with PS: D-limonene and PS: Toluene

Devisetty Subramanyam, Manopriya

04 November 2014

This work investigates the fabrication, process optimization, and characterization of cobalt oxide-antimony doped tin oxide (CoO-ATO) nanofibersusing polystyrene (PS) solutions with toluene orD-limonene as solvents. These nanofibers are produced by anelectrospinning process. Nanofibers are fabricated using polymeric solutions of CoO doped ATO and mixtures of PS: D-limonene and PS:toluene. PSis a base aromatic organic polymer, a non-toxic material, and a versatile catalyst for fiber formation. PSsolutions are made by mixing polystyrene beads and D-limonene or toluene at specific weight percentages. These polymeric solutions of PS: D-limonene and PS:toluene are then mixed with CoO-ATO at various weight percentages. The two solutions are electrospun and the best process parameters optimized to obtain nanofibers with limited beading. Process optimization is completed by analyzing how changes in the electrospinningexperimental set up impact nanofiber formation and production efficiency (speed of formation). CoO-ATO nanofibers are characterizedby scanning electron microscopy, hydrophobicity via contact angle measurements, and viscosity measurements. Additional analysis is conducted to evaluate the environmental impact of using two different solvents to fabricate the CoO-ATO nanofibers. In this project, I was able to successfully produce novel nanofiber membranes of CoO-ATOusing two different solvents. These investigations were conducted and nanofiberprocess optimized to provide a technological contribution to future industrial scaleproductions of thermally reflective materials.

Electrospinning

Infrared

Life Cycle Analysis

Nanofiber Mesh

Thermally Reflective

Electrical and Computer Engineering

Nanotechnology Fabrication