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Gas Transport Mechanisms in Polymer-Grafted Nanoparticle MembranesTannenbaum, Robert J. January 2023 (has links)
Carbon capture and related gas separation processes are critical tools in our efforts to combat climate change. While polymer membranes are seen as a central construct to achieve these goals, their performance needs further improvement to meet current sustainability objectives. It is in this context that membranes composed of polymer-grafted nanoparticles (GNPs) become highly germane. Chemically tethering the available polymer to the nanoparticle (NP) surface in GNP systems helps mitigate difficulties controlling nanoparticle dispersion common when incorporating inorganic filler NPs into polymer (i.e., mixed matrix membranes (MMMs)). Previous work has shown that gas transport in pure GNP membranes can be strongly enhanced relative to that in the corresponding neat polymer. Additionally, we demonstrated that larger gases display greater degrees of permeability enhancement than smaller ones. This work explores the underlying mechanisms governing the unique gas transport behavior observed in GNPs, with the goal of designing materials possessing superior transport properties that can be known and manipulated a priori.
We begin with the identification of transport mechanisms for penetrants of different sizes through an exploration of the heterogenous nature of GNPs. In the limit of moderate-to-high grafting density (the number of chains tethered per unit surface area), the chains are overcrowded near the surface and assume extended conformations termed “polymer brushes”. These brushes comprise two regimes: (1) a dry zone of higher polymer stretching closer to the NP surface and (2) the interstitial spaces in the multibody packing of lower polymer density. We find that larger penetrants such as CH₄, with low solubilities, preferentially sorb into the interstitial spaces in the NP packing prior to diffusing through stretched chains in the dry brush region. The nature of small gas permeability enhancement, on the other hand, is due primarily to enhancements in penetrant diffusion through the stretched chain region close to the NP surface – this is because these gases have high enough solubilities to be present everywhere in the polymer layer.
Such solubility differences enable the direct control over penetrant transport through the disparate regions of the polymer brush in mixed-gas environments relevant to operation. Elevated CO₂ content, through increasing feed concentrations at higher pressures, yields increased CH₄ permeability and an associated reduction in mixed-gas selectivity relative to ideal gas analogs. Additionally, high-pressure conditioning with CO₂ evidently dilates the material (due to gas adsorption) in a manner that is apparently not recoverable after a pressure decrease.
An alternative handle to control penetrant transport is to manipulate the physical brush structure. Such morphological control is accomplished through variations in preparation methodology; in particular, the rate of solvent evaporation in solution-cast samples plays a significant role in dictating the final structure of the jammed colloidal glass. Utilizing high-pressure conditioning in CO₂ as a concentration quench, we combine morphological control over the brush structure with selective penetrant manipulation to dilate the overcrowded brush regime and enhance gas transport performance. Leveraging the colloidal glass nature of GNPs in this way enables the formation of quasi-equilibrium structures with even greater amounts of “free volume”.
The remaining chapters focus on employing our knowledge of the gas transport mechanisms in these materials to aid in future experimental design and to form mechanically resilient materials. Implementing a simulated design-of-experiments loop, we find that a surprisingly minimal amount of experimental data is necessary to effectively model the transport properties of new materials to within practical experimental error. Selectively altering the chemistry of specific chain regions achieved slight enhancement in membrane selectivity while significantly improving material toughness and ultimate utility. Our enhanced understanding of gas transport mechanisms in polymer-grafted nanoparticle membranes will aid in the design and implementation of membranes with tunable separation performance through direct control of how penetrants transport and via morphological changes to the brush structure.
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Συγκριτική μελέτη πρωτονίωσης / εμποτισμού πολυμερικών ηλεκτρολυτικών μεμβρανών για στοιχεία καυσίμου υψηλής θερμοκρασίαςΒόγλη, Ευφροσύνη 18 June 2009 (has links)
Η συγκεκριμένη διατριβή ειδίκευσης αποτελεί μια προσπάθεια συγκριτικής μελέτης νέων πολυμερικών ηλεκτρολυτικών μεμβρανών για στοιχεία καύσιμου υψηλής θερμοκρασίας, με το PBI (πολυβενζιμιδαζόλιο).
Αρχικά πραγματοποιήθηκε μια φασματοσκοπική και ηλεκτροχημική μελέτη των μεμβρανών. Πιο συγκεκριμένα μελετήθηκαν η μεμβράνη ADVENT TPS® και τα μίγματα SFSX-PBIY (σουλφονωμένο δεκαφλουοροδιφαινύλιο με εξαφλουοροισοπροπυλενό- διφαινολη - πολυβενζιμιδαζόλιο) εμποτισμένα με πυκνό διάλυμα φωσφορικού οξέος 85%. Η ηλεκτροχημική μελέτη αφορούσε τη μέτρηση της ιοντικής αγωγιμότητας συναρτήσει του βαθμού εμποτισμού, ενώ η φασματοσκοπική μελέτη πραγματοποιήθηκε με τη χρήση δονητικής φασματοσκοπίας FT-IR και FT-Raman επίσης συναρτήσει του βαθμού εμποτισμού, κάνοντας έτσι δυνατή τη συσχέτιση των δονητικών φασμάτων με την ιοντική αγωγιμότητα.
Με τη φασματοσκοπία FT-Raman μελετήθηκε το φαινόμενο της πρωτονίωσης των μεμβρανών με το φωσφορικό οξύ. Η συσχέτιση του βαθμού εμποτισμού με τις σχετικές εντάσεις συγκεκριμένων κορυφών (1589 cm-1 και 1632 cm-1 για το TPS και 1593 cm-1 και 1570 cm-1 για τα μίγματα SFSX-PBIY) δίνει την δυνατότητα υπολογισμού των μορίων φωσφορικού οξέος που απαιτούνται για να πρωτονιώσουν έναν πυριδινικό δακτύλιο στην πρώτη περίπτωση και δυο ιμιδαζολικούς δακτυλίους στην δεύτερη.
Το δεύτερο μέρος της μελέτης αφορούσε την εξέταση του φαινομένου αποβολής του εμποτίζοντος μέσου από την μεμβράνη, γεγονός που αποτελεί το κυριότερο πρόβλημα μη εμπορικής διαθεσιμότητας κυψελίδων καυσίμου αγωγής πρωτονίων μέσω ηλεκτρολυτικής πολυμερικής μεμβράνης υψηλών θερμοκρασιών.
Μέσω φασματοσκοπίας FT-Raman παρακολουθούμε τη διαδικασία της πλήρους πρωτονίωσης των μεμβρανών που είναι προαπαιτούμενο για τον περαιτέρω εμποτισμό τους. Στη συνέχεια ακολουθεί η διαδικασία σταθεροποίησης τους υπό θέρμανση και υπό θέρμανση και πίεση ταυτόχρονα σε διαφορετικές θερμοκρασίες, που μας επιτρέπει να υπολογίσουμε τα μόρια του εμποτίζοντος μέσου που συγκρατεί τελικά η μεμβράνη και την ποιοτική τους κατάσταση στο τέλος της διαδικασίας. / Proton exchange membrane fuel cells (PEMFCs) have gained international attention as candidates for alternative automobile and stationary power sources. The electrolyte is a polymeric membrane. Poly(benzimidazole), PBI, has been widely studied with various strong acids and bases as a promising electrolyte for high temperature PEM fuel cells but it seems that the doping agent is leaching out with time, something that causes problems in their operation. For these reasons have been developed novel polymeric membranes that can be used as electrolytes at HT-PEMFCs. Two promising membranes are the ADVENT TPS® that contains pyridine units and alternative PBI polymer blends with partially fluorinated polyether ionomer (SFS).
In this work our efforts were primarily concentrated to the examination via FT-IR and FT-Raman of the structural characteristics of the membranes and via the four probe interruption method to the examination of their electrochemical properties. The emphasis was given to the correlation of the spectroscopic evidence of acid interactions with the doping level attained and the ionic conductivity obtained.
Then, we were concentrated to the examination via FT-Raman of the leaching out of the doping agent from the membranes that were protonated /doped by high concentrated phosphoric acid in different doping levels and in different temperatures. The influence of the doping temperature and the effect of the heating, under pressure or without, to the decisive leaching out of an acid-doped PBI membrane were investigated. Both novel membranes seem to bond phosphoric acid better than PBI.
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Synthesis and characterization of polysulfone/nanoclay/polyethylene oxide composite ultrafiltration membranes. / Síntese e caracterização de membranas compósitas de polisulfona para ultrafiltração modificadas com nanoargila e polióxido de etileno.Rodrigues, Raphael 15 December 2015 (has links)
Membrane structure modification is a common approach to enhance membrane properties and performance. For example, the addition of dopants to the membrane casting solution has been observed to increase hydrophilicity, alter surface and internal pore structure, increase thermal and mechanical resistance, and impart anti-fouling properties. In this study, it was evaluated how the addition of individual and simultaneous nanoclay and polyethylene oxide (PEO) dopants affected the structure and performance of polysulfone (PSU) ultrafiltration membranes. Membrane performance was evaluated in the cross-flow configuration. The pure water permeability of the neat PSU membrane was 15 L/m².h.bar and at the optimal dosage of the individually doped membranes was 1.5% weight nanoclay to PSU and 5% weight PEO to PSU resulting in permeability of 56 and 237 L/m².h.bar, respectively. Simultaneous doping using the optimal individual weight percentages had a lower effect resulting in a permeability of 192 L/m².h.bar, in contrast the simultaneous addition of 4.5% nanoclay and 5% PEO had a higher effect resulting in a permeability of 319 L/m².h.bar. The control membrane was compared to the referred membranes and with the 4.5% nanoclay membrane (best permeability only when combined with PEO). These membranes were further examined to determine dopant effects on pore microstructure, superficial charge, separation performance, and fouling susceptibility. In general, doping with nanoclay improved membrane thermal/mechanical resistance and permeability with minimal loss in rejection. Doping with PEO resulted in a greater permeability as compared to nanoclay; however, PEO doping decreased rejection, mechanical resistance, and increased irreversible fouling. Thus, both advantageous and disadvantageous effects should be considered when selecting a dopant to optimize membrane performance. / A modificação da estrutura de membranas é uma abordagem utilizada para melhorar as propriedades de membranas e desempenho de um sistema. Por exemplo, a adição de dopantes na solução de síntese da membrana permite aumentar a hidrofilicidade, alterar a estrutura de poros superficiais e internos e conferir propriedades anti-depósitos. Neste estudo, foi avaliada como a adição de óxido de polietileno e de nano-argila afetam a estrutura e desempenho de membranas de ultrafiltração de polisulfona (PSU). O desempenho da membrana foi avaliado na configuração de fluxo paralelo (cross-flow). A permeabilidade média à água pura da membrana de PSU pura foi de 15 L/m2.h.bar. As dosagem ótimas das membranas dopadas individualmente foram de 1,5% em massa de PSU para nano-argila e 5% em massa de PSU para PEO, resultando em permeabilidades médias de 56 e 237 L/m2.h.bar, respectivamente. A dopagem simultânea usando ambas as percentagens individuais ótimas teve um efeito menor do que o esperado, resultando em uma permeabilidade média de 192 L/m2.h.bar. Em contraste, verificou-se que a adição simultânea de 4,5% de nano-argila combinada com 5% de PEO teve um efeito maior do que o uso isolado dos aditivos, resultando em uma permeabilidade média de 319 L/m2.h.bar. Desta forma, a membrana de controle foi comparada com as referidas membranas e com membranas compostas somente por nano-argila a 4,5. Estas membranas foram ainda examinadas em detalhes para determinar os efeitos dos dopantes na microestrutura dos poros, cargas superficiais, desempenho da separação, sensibilidade à formação de depósitos, rugosidade superficial e propriedades térmicas e mecânicas. Verificou-se que a dopagem com nano-argila melhora a resistência térmica e mecânica e a permeabilidade das membranas, com uma perda mínima na rejeição. A dopagem com PEO resultou em um aumento notável de permeabilidade em comparação com a adição individual de nano-argila. No entanto, a capacidade de rejeição e resistência térmica e mecânica destas membranas diminuem e a formação de depósitos irreversíveis aumenta. Desta forma, avalia-se que para a utilização de mais de um tipo de dopante os efeitos vantajosos e desvantajosos devem ser considerados individualmente e em conjunto no esforço de se otimizar o desempenho de sistemas de membranas.
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Synthesis and characterization of polysulfone/nanoclay/polyethylene oxide composite ultrafiltration membranes. / Síntese e caracterização de membranas compósitas de polisulfona para ultrafiltração modificadas com nanoargila e polióxido de etileno.Raphael Rodrigues 15 December 2015 (has links)
Membrane structure modification is a common approach to enhance membrane properties and performance. For example, the addition of dopants to the membrane casting solution has been observed to increase hydrophilicity, alter surface and internal pore structure, increase thermal and mechanical resistance, and impart anti-fouling properties. In this study, it was evaluated how the addition of individual and simultaneous nanoclay and polyethylene oxide (PEO) dopants affected the structure and performance of polysulfone (PSU) ultrafiltration membranes. Membrane performance was evaluated in the cross-flow configuration. The pure water permeability of the neat PSU membrane was 15 L/m².h.bar and at the optimal dosage of the individually doped membranes was 1.5% weight nanoclay to PSU and 5% weight PEO to PSU resulting in permeability of 56 and 237 L/m².h.bar, respectively. Simultaneous doping using the optimal individual weight percentages had a lower effect resulting in a permeability of 192 L/m².h.bar, in contrast the simultaneous addition of 4.5% nanoclay and 5% PEO had a higher effect resulting in a permeability of 319 L/m².h.bar. The control membrane was compared to the referred membranes and with the 4.5% nanoclay membrane (best permeability only when combined with PEO). These membranes were further examined to determine dopant effects on pore microstructure, superficial charge, separation performance, and fouling susceptibility. In general, doping with nanoclay improved membrane thermal/mechanical resistance and permeability with minimal loss in rejection. Doping with PEO resulted in a greater permeability as compared to nanoclay; however, PEO doping decreased rejection, mechanical resistance, and increased irreversible fouling. Thus, both advantageous and disadvantageous effects should be considered when selecting a dopant to optimize membrane performance. / A modificação da estrutura de membranas é uma abordagem utilizada para melhorar as propriedades de membranas e desempenho de um sistema. Por exemplo, a adição de dopantes na solução de síntese da membrana permite aumentar a hidrofilicidade, alterar a estrutura de poros superficiais e internos e conferir propriedades anti-depósitos. Neste estudo, foi avaliada como a adição de óxido de polietileno e de nano-argila afetam a estrutura e desempenho de membranas de ultrafiltração de polisulfona (PSU). O desempenho da membrana foi avaliado na configuração de fluxo paralelo (cross-flow). A permeabilidade média à água pura da membrana de PSU pura foi de 15 L/m2.h.bar. As dosagem ótimas das membranas dopadas individualmente foram de 1,5% em massa de PSU para nano-argila e 5% em massa de PSU para PEO, resultando em permeabilidades médias de 56 e 237 L/m2.h.bar, respectivamente. A dopagem simultânea usando ambas as percentagens individuais ótimas teve um efeito menor do que o esperado, resultando em uma permeabilidade média de 192 L/m2.h.bar. Em contraste, verificou-se que a adição simultânea de 4,5% de nano-argila combinada com 5% de PEO teve um efeito maior do que o uso isolado dos aditivos, resultando em uma permeabilidade média de 319 L/m2.h.bar. Desta forma, a membrana de controle foi comparada com as referidas membranas e com membranas compostas somente por nano-argila a 4,5. Estas membranas foram ainda examinadas em detalhes para determinar os efeitos dos dopantes na microestrutura dos poros, cargas superficiais, desempenho da separação, sensibilidade à formação de depósitos, rugosidade superficial e propriedades térmicas e mecânicas. Verificou-se que a dopagem com nano-argila melhora a resistência térmica e mecânica e a permeabilidade das membranas, com uma perda mínima na rejeição. A dopagem com PEO resultou em um aumento notável de permeabilidade em comparação com a adição individual de nano-argila. No entanto, a capacidade de rejeição e resistência térmica e mecânica destas membranas diminuem e a formação de depósitos irreversíveis aumenta. Desta forma, avalia-se que para a utilização de mais de um tipo de dopante os efeitos vantajosos e desvantajosos devem ser considerados individualmente e em conjunto no esforço de se otimizar o desempenho de sistemas de membranas.
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PEBAX-based mixed matrix membranes for post-combustion carbon captureBryan, Nicholas James January 2018 (has links)
Polymeric membranes exhibit a trade-off between permeability and selectivity in gas separations which limits their viability as an economically feasible post-combustion carbon capture technology. One approach to improve the separation properties of polymeric membranes is the inclusion of particulate materials into the polymer matrix to create what are known as mixed matrix membranes (MMMs). By combining the polymer and particulate phases, beneficial properties of both can be seen in the resulting composite material. One of the most notable challenges in producing mixed matrix membranes is in the formation of performance-hindering defects at the polymer-filler interface. Non-selective voids or polymer chain rigidification are but two non-desirable effects which can be observed. The material selection and synthesis route are key to minimising these defects. Thin membranes are also highly desirable to achieve greater gas fluxes and improved economical separation processes. Hence smaller nano-sized particles are of particular interest to minimise the disruption to the polymer matrix. This is a challenge due to the tendency of some small particles to form agglomerations. This work involved introducing novel nanoscale filler particles into PEBAX MH1657, a commercially available block-copolymer consisting of poly(ethylene oxide) and nylon 6 chains. Poly(ether-b-amide) materials possess an inherently high selectivity for the CO2/N2 separation due to polar groups in the PEO chain but suffer from low permeabilities. Mixed matrix membranes were fabricated with PEBAX MH1657 primarily using two filler particles, nanoscale ZIF-8 and novel nanoscale MCM-41 hollow spheres. This work primarily investigated the effects of the filler loading on both the morphology and gas transport properties of the composite materials. The internal structure of the membranes was examined using scanning electron microscopy (SEM), and the gas transport properties determined using a bespoke time-lag gas permeation apparatus. ZIF-8 is a zeolitic imidazolate framework which possesses small pore windows that may favour CO2 transport over that of N2. ZIF-8-PEBAX membranes were successfully synthesised up to 7wt.%. It was found that for filler loadings below 5wt.%, the ZIF-8 was well dispersed within the polymer phase. At these loadings modest increases in the CO2 permeability coeffcient of 0-20% compared to neat PEBAX were observed. Above this 5wt.% loading large increases in both CO2, N2 and He permeability coeffcients coincided with the presence of large micron size clusters formed of hundreds of filler ZIF-8 particles. The increases in permeability were attributed to voids observed within the clusters. MCM-41 is a metal organic framework that has seen notable interest in the field of carbon capture, due to its tunable pore size and ease of functionalisation. Two types of novel MCM-41 hollow sphere (MCM-41-HS) of varying pore size were incorporated into PEBAX and successfully used to fabricate MMMs up to 10wt.%. SEM showed the MCM-41 generally interacted well with the polymer with no signs of voids and was generally well dispersed. However, some samples of intermediate loading in both cases showed highly asymmetric distribution of nanoparticles and high particle density regions near one external face of the membrane which also showed the highest CO2 permeability coeffcients. It is suspected that these high permeabilities are due to the close proximity of nanoparticles permitting these regions to act in a similar way to percolating networks. It was determined that there was no observable effect of the varying pore size which was expected given the transport in the pores should be governed by Knudsen diffusion.
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Microestruturação de membranas de poli (tereftalato de etileno) por microfeixe de íonsSouza, Cláudia Telles de January 2013 (has links)
Neste trabalho, o processo de estruturação por microfeixe de íons foi utilizado para a produção de membranas microporosas em folhas comerciais de PET. O processo de estruturação por microfeixe de íons consiste basicamente na interação direta entre um feixe de íons de dimensões micrométricas com o material em questão. As zonas modificadas pelo feixe são removidas do restante do material através de um processo químico. Nesse contexto, durante o desenvolvimento deste trabalho, sistemáticas experimentais para o processo de estruturação foram desenvolvidas. Com o intuito de operacionalizar a linha de microfeixe presente no Laboratório de Implantação Iônica da UFRGS, foi necessário realizar um estudo aprofundado sobre o funcionamento de todo o sistema, verificando problemas e explorando a potencialidade de técnicas não convencionais de análise de materiais. O estudo sobre a sistemática de estruturação ocorreu através da investigação de parâmetros clássicos, como fluência utilizada durante a irradiação e tempo de ataque químico. Para atingir tais objetivos, amostras de poli (tereftalato de etileno) (Mylar) de 12 μm foram irradiadas com microfeixe de íons (H+ e He++) com energias de 3 e 2,2 MeV e fluências que variaram entre 1 x 1011 e 6 x 1015 íons/cm2. Posteriormente à irradiação, as amostras foram submetidas a um ataque químico com solução alcalina de hidróxido de sódio 6 M durante tempos que variaram de 0,5 à 60 minutos. A temperatura do ataque em todos os casos se manteve fixa em 60°C. A caracterização das amostras foi realizada através de microscopia eletrônica de varredura (MEV) e por microscopia de transmissão iônica (STIM). As amostras também foram caracterizadas através de medidas elétricas utilizando um circuito de corrente alternada. O processo de enxertia (grafting) foi testado nas membranas estruturadas, utilizando um hidrogel de PNIPAAm com concentrações de 0,340, 0,450 e 0,700 g/L. Tais resultados também foram analisados através de MEV. O estudo sobre a linha de microfeixe permitiu verificar a existência de problemas relacionados ao registro da carga elétrica durante as irradiações. Além disso, para o ajuste do foco do feixe de íons, foram feitas curvas de calibração de corrente para as lentes magnéticas considerando diferentes energias de feixe. O processo de estruturação através da técnica de microfeixe de íons se mostrou eficaz para a produção de estruturas regulares e definidas em folhas de PET. A fluência ótima de prótons a ser utilizada nos processos de estruturação foi estimada em 6 x 1014 íons/cm2. Para esta fluência, tempos de ataque químico inferiores a 1 minuto já são suficientes para corroer toda a parte irradiada. Entretanto, tempos um pouco mais longos (e.g. 2 minutos) tornam o processo mais reprodutível. Com relação à geometria das estruturas fabricadas, observou-se irregularidades em estruturas que, em princípio, deveriam ser simétricas. Esse problema foi atribuído à assimetria do feixe, proveniente de ajustes dos parâmetros de colimação do feixe. Finalmente, o estudo do processo de enxertia mostrou que o hidrogel adere nas paredes das estruturas, porém não as preenche. Para concentrações elevadas (e.g. 0,7 g/L) o processo não é tão eficiente, sendo que não é verificada a redução da área das microestruturas pela inserção do hidrogel. As medidas elétricas mostraram a existência de regimes distintos e dependentes da frequência da corrente alternada. Os polímeros apresentaram basicamente comportamentos resistivo e capacitivo. / In this work, the process of irradiation of PET foils with ion beams in the micrometer size range was used for the production of microporous membranes. Basically, this process consists on the direct interaction between the ion beam and the material under study. The regions modified by the beam are removed from the material through a chemical process. In this context, experimental procedures for the production process of the membranes were developed during the course of this work. In order to make the microbeam station of the Ion Implantation Laboratory of the Federal University of Rio Grande do Sul (UFRGS), it was necessary to perform a thorough study of the operational parameters of the system, thus allowing a proper identification of problems and providing grounds for pushing the technique to the frontier of materials science. To achieve such objectives, foils of polyethylene terephtalate (Mylar®) 12 μm thick were irradiated with H+ and He++ ions with 3 e 2,2 MeV respectively. Fluencies varied from 1 x 1011 and 6 x 1015 ions/cm2. After the irradiation, the foils were submitted to an etching procedure using alkaline solution of sodium hydroxide at 6 M during periods of time varying from 0,5 to 60 minutes. In all cases, the temperature of the etching was fixed at 60°C. The characterization of the samples was performed through scanning electron microscopy (SEM) and scanning transmission ion microscopy (STIM). The samples also were characterized by electric measurements using an AC current circuit. The process of grafting was tested on the structured membranes using a PNIPAAm hydrogel with concentrations of 0,340, 0,450 and 0,700 g/L. The results of this study were also analyzed through MEV. With the present study, it was possible to pinpoint problems related to the integration and recording of the charge during the irradiations. Besides that, calibration curves were obtained relating the electric currents needed on the magnetic lenses for an optimal ion beam focus and the beam energy. The irradiation process with ion beam proved itself efficient for the production of regular patterns on PET foils. The optimum dose of prótons to be used on the patterning processes was estimated in 6 x 1014 ions/cm2. For this dose, etching times smaller than 1 minute were enough to remove all the irradiated area. However, times slightly longer (e.g. 2 minutes) make the process more reproducible. Regarding the geometry of the patterns generated by the ion irradiation, asymmetries were observed on structures that were supposed to be symmetric. This problem was attributed to the asymmetry of the beam spot on the target due to the settings of the objective slits that collimates the beam. The study of the grafting process showed that the hydrogel adheres to the structures walls, but does not fill it. For high concentrations (e.g. 0,7 g/L), the process is not efficient, since no reduction of the area of the microstructures by the insertion of the hydrogel was observed. The electric measurements showed the existence of distinct regimes as a function of the frequency of the alternate current. Basically, the polymer foils present resistive and capacitive behaviors.
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Microestruturação de membranas de poli (tereftalato de etileno) por microfeixe de íonsSouza, Cláudia Telles de January 2013 (has links)
Neste trabalho, o processo de estruturação por microfeixe de íons foi utilizado para a produção de membranas microporosas em folhas comerciais de PET. O processo de estruturação por microfeixe de íons consiste basicamente na interação direta entre um feixe de íons de dimensões micrométricas com o material em questão. As zonas modificadas pelo feixe são removidas do restante do material através de um processo químico. Nesse contexto, durante o desenvolvimento deste trabalho, sistemáticas experimentais para o processo de estruturação foram desenvolvidas. Com o intuito de operacionalizar a linha de microfeixe presente no Laboratório de Implantação Iônica da UFRGS, foi necessário realizar um estudo aprofundado sobre o funcionamento de todo o sistema, verificando problemas e explorando a potencialidade de técnicas não convencionais de análise de materiais. O estudo sobre a sistemática de estruturação ocorreu através da investigação de parâmetros clássicos, como fluência utilizada durante a irradiação e tempo de ataque químico. Para atingir tais objetivos, amostras de poli (tereftalato de etileno) (Mylar) de 12 μm foram irradiadas com microfeixe de íons (H+ e He++) com energias de 3 e 2,2 MeV e fluências que variaram entre 1 x 1011 e 6 x 1015 íons/cm2. Posteriormente à irradiação, as amostras foram submetidas a um ataque químico com solução alcalina de hidróxido de sódio 6 M durante tempos que variaram de 0,5 à 60 minutos. A temperatura do ataque em todos os casos se manteve fixa em 60°C. A caracterização das amostras foi realizada através de microscopia eletrônica de varredura (MEV) e por microscopia de transmissão iônica (STIM). As amostras também foram caracterizadas através de medidas elétricas utilizando um circuito de corrente alternada. O processo de enxertia (grafting) foi testado nas membranas estruturadas, utilizando um hidrogel de PNIPAAm com concentrações de 0,340, 0,450 e 0,700 g/L. Tais resultados também foram analisados através de MEV. O estudo sobre a linha de microfeixe permitiu verificar a existência de problemas relacionados ao registro da carga elétrica durante as irradiações. Além disso, para o ajuste do foco do feixe de íons, foram feitas curvas de calibração de corrente para as lentes magnéticas considerando diferentes energias de feixe. O processo de estruturação através da técnica de microfeixe de íons se mostrou eficaz para a produção de estruturas regulares e definidas em folhas de PET. A fluência ótima de prótons a ser utilizada nos processos de estruturação foi estimada em 6 x 1014 íons/cm2. Para esta fluência, tempos de ataque químico inferiores a 1 minuto já são suficientes para corroer toda a parte irradiada. Entretanto, tempos um pouco mais longos (e.g. 2 minutos) tornam o processo mais reprodutível. Com relação à geometria das estruturas fabricadas, observou-se irregularidades em estruturas que, em princípio, deveriam ser simétricas. Esse problema foi atribuído à assimetria do feixe, proveniente de ajustes dos parâmetros de colimação do feixe. Finalmente, o estudo do processo de enxertia mostrou que o hidrogel adere nas paredes das estruturas, porém não as preenche. Para concentrações elevadas (e.g. 0,7 g/L) o processo não é tão eficiente, sendo que não é verificada a redução da área das microestruturas pela inserção do hidrogel. As medidas elétricas mostraram a existência de regimes distintos e dependentes da frequência da corrente alternada. Os polímeros apresentaram basicamente comportamentos resistivo e capacitivo. / In this work, the process of irradiation of PET foils with ion beams in the micrometer size range was used for the production of microporous membranes. Basically, this process consists on the direct interaction between the ion beam and the material under study. The regions modified by the beam are removed from the material through a chemical process. In this context, experimental procedures for the production process of the membranes were developed during the course of this work. In order to make the microbeam station of the Ion Implantation Laboratory of the Federal University of Rio Grande do Sul (UFRGS), it was necessary to perform a thorough study of the operational parameters of the system, thus allowing a proper identification of problems and providing grounds for pushing the technique to the frontier of materials science. To achieve such objectives, foils of polyethylene terephtalate (Mylar®) 12 μm thick were irradiated with H+ and He++ ions with 3 e 2,2 MeV respectively. Fluencies varied from 1 x 1011 and 6 x 1015 ions/cm2. After the irradiation, the foils were submitted to an etching procedure using alkaline solution of sodium hydroxide at 6 M during periods of time varying from 0,5 to 60 minutes. In all cases, the temperature of the etching was fixed at 60°C. The characterization of the samples was performed through scanning electron microscopy (SEM) and scanning transmission ion microscopy (STIM). The samples also were characterized by electric measurements using an AC current circuit. The process of grafting was tested on the structured membranes using a PNIPAAm hydrogel with concentrations of 0,340, 0,450 and 0,700 g/L. The results of this study were also analyzed through MEV. With the present study, it was possible to pinpoint problems related to the integration and recording of the charge during the irradiations. Besides that, calibration curves were obtained relating the electric currents needed on the magnetic lenses for an optimal ion beam focus and the beam energy. The irradiation process with ion beam proved itself efficient for the production of regular patterns on PET foils. The optimum dose of prótons to be used on the patterning processes was estimated in 6 x 1014 ions/cm2. For this dose, etching times smaller than 1 minute were enough to remove all the irradiated area. However, times slightly longer (e.g. 2 minutes) make the process more reproducible. Regarding the geometry of the patterns generated by the ion irradiation, asymmetries were observed on structures that were supposed to be symmetric. This problem was attributed to the asymmetry of the beam spot on the target due to the settings of the objective slits that collimates the beam. The study of the grafting process showed that the hydrogel adheres to the structures walls, but does not fill it. For high concentrations (e.g. 0,7 g/L), the process is not efficient, since no reduction of the area of the microstructures by the insertion of the hydrogel was observed. The electric measurements showed the existence of distinct regimes as a function of the frequency of the alternate current. Basically, the polymer foils present resistive and capacitive behaviors.
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Microestruturação de membranas de poli (tereftalato de etileno) por microfeixe de íonsSouza, Cláudia Telles de January 2013 (has links)
Neste trabalho, o processo de estruturação por microfeixe de íons foi utilizado para a produção de membranas microporosas em folhas comerciais de PET. O processo de estruturação por microfeixe de íons consiste basicamente na interação direta entre um feixe de íons de dimensões micrométricas com o material em questão. As zonas modificadas pelo feixe são removidas do restante do material através de um processo químico. Nesse contexto, durante o desenvolvimento deste trabalho, sistemáticas experimentais para o processo de estruturação foram desenvolvidas. Com o intuito de operacionalizar a linha de microfeixe presente no Laboratório de Implantação Iônica da UFRGS, foi necessário realizar um estudo aprofundado sobre o funcionamento de todo o sistema, verificando problemas e explorando a potencialidade de técnicas não convencionais de análise de materiais. O estudo sobre a sistemática de estruturação ocorreu através da investigação de parâmetros clássicos, como fluência utilizada durante a irradiação e tempo de ataque químico. Para atingir tais objetivos, amostras de poli (tereftalato de etileno) (Mylar) de 12 μm foram irradiadas com microfeixe de íons (H+ e He++) com energias de 3 e 2,2 MeV e fluências que variaram entre 1 x 1011 e 6 x 1015 íons/cm2. Posteriormente à irradiação, as amostras foram submetidas a um ataque químico com solução alcalina de hidróxido de sódio 6 M durante tempos que variaram de 0,5 à 60 minutos. A temperatura do ataque em todos os casos se manteve fixa em 60°C. A caracterização das amostras foi realizada através de microscopia eletrônica de varredura (MEV) e por microscopia de transmissão iônica (STIM). As amostras também foram caracterizadas através de medidas elétricas utilizando um circuito de corrente alternada. O processo de enxertia (grafting) foi testado nas membranas estruturadas, utilizando um hidrogel de PNIPAAm com concentrações de 0,340, 0,450 e 0,700 g/L. Tais resultados também foram analisados através de MEV. O estudo sobre a linha de microfeixe permitiu verificar a existência de problemas relacionados ao registro da carga elétrica durante as irradiações. Além disso, para o ajuste do foco do feixe de íons, foram feitas curvas de calibração de corrente para as lentes magnéticas considerando diferentes energias de feixe. O processo de estruturação através da técnica de microfeixe de íons se mostrou eficaz para a produção de estruturas regulares e definidas em folhas de PET. A fluência ótima de prótons a ser utilizada nos processos de estruturação foi estimada em 6 x 1014 íons/cm2. Para esta fluência, tempos de ataque químico inferiores a 1 minuto já são suficientes para corroer toda a parte irradiada. Entretanto, tempos um pouco mais longos (e.g. 2 minutos) tornam o processo mais reprodutível. Com relação à geometria das estruturas fabricadas, observou-se irregularidades em estruturas que, em princípio, deveriam ser simétricas. Esse problema foi atribuído à assimetria do feixe, proveniente de ajustes dos parâmetros de colimação do feixe. Finalmente, o estudo do processo de enxertia mostrou que o hidrogel adere nas paredes das estruturas, porém não as preenche. Para concentrações elevadas (e.g. 0,7 g/L) o processo não é tão eficiente, sendo que não é verificada a redução da área das microestruturas pela inserção do hidrogel. As medidas elétricas mostraram a existência de regimes distintos e dependentes da frequência da corrente alternada. Os polímeros apresentaram basicamente comportamentos resistivo e capacitivo. / In this work, the process of irradiation of PET foils with ion beams in the micrometer size range was used for the production of microporous membranes. Basically, this process consists on the direct interaction between the ion beam and the material under study. The regions modified by the beam are removed from the material through a chemical process. In this context, experimental procedures for the production process of the membranes were developed during the course of this work. In order to make the microbeam station of the Ion Implantation Laboratory of the Federal University of Rio Grande do Sul (UFRGS), it was necessary to perform a thorough study of the operational parameters of the system, thus allowing a proper identification of problems and providing grounds for pushing the technique to the frontier of materials science. To achieve such objectives, foils of polyethylene terephtalate (Mylar®) 12 μm thick were irradiated with H+ and He++ ions with 3 e 2,2 MeV respectively. Fluencies varied from 1 x 1011 and 6 x 1015 ions/cm2. After the irradiation, the foils were submitted to an etching procedure using alkaline solution of sodium hydroxide at 6 M during periods of time varying from 0,5 to 60 minutes. In all cases, the temperature of the etching was fixed at 60°C. The characterization of the samples was performed through scanning electron microscopy (SEM) and scanning transmission ion microscopy (STIM). The samples also were characterized by electric measurements using an AC current circuit. The process of grafting was tested on the structured membranes using a PNIPAAm hydrogel with concentrations of 0,340, 0,450 and 0,700 g/L. The results of this study were also analyzed through MEV. With the present study, it was possible to pinpoint problems related to the integration and recording of the charge during the irradiations. Besides that, calibration curves were obtained relating the electric currents needed on the magnetic lenses for an optimal ion beam focus and the beam energy. The irradiation process with ion beam proved itself efficient for the production of regular patterns on PET foils. The optimum dose of prótons to be used on the patterning processes was estimated in 6 x 1014 ions/cm2. For this dose, etching times smaller than 1 minute were enough to remove all the irradiated area. However, times slightly longer (e.g. 2 minutes) make the process more reproducible. Regarding the geometry of the patterns generated by the ion irradiation, asymmetries were observed on structures that were supposed to be symmetric. This problem was attributed to the asymmetry of the beam spot on the target due to the settings of the objective slits that collimates the beam. The study of the grafting process showed that the hydrogel adheres to the structures walls, but does not fill it. For high concentrations (e.g. 0,7 g/L), the process is not efficient, since no reduction of the area of the microstructures by the insertion of the hydrogel was observed. The electric measurements showed the existence of distinct regimes as a function of the frequency of the alternate current. Basically, the polymer foils present resistive and capacitive behaviors.
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Effects of oxidation states of Copper (Cu), Nickel (Ni), Palladium (Pd) and Silver (Ag) on rejection by nanofiltration membranesBrooms, Thabo John 06 1900 (has links)
Thesis (M. Tech.(Chemistry)--Vaal University of Technology)), 2010 / Mining industry produces metals which are economical and serve as high valuable commodities in South Africa. This country is regarded as the world leading producer of precious metals such as platinum group metals (PGMs). Silver (Ag), which is also a precious metal, contribute to the country’s economy wealth due to its significance during industrial applications. Base metals such as copper (Cu) and nickel (Ni), though they are low valued, play a significant role in the republics economic wealth. Mining wastewater contains some of these metals, which end up polluting the environment. A possibility to recover this was investigated using NF membranes. Mine effluent was simulated by using relevant reagents.
Characterization of NF90, NF- and NF270 membranes, was done by using scanning electron microscopy (SEM), clean water permeability, single charged salts of NaCl and MgCl2 and binary mixture of NaCl/MgCl2 studies. All the rejection experiments were conducted at pH 2.0 with varying pressure and concentrations. Flux measurements indicated that water permeability through the membranes trend, NF270 > NF90 > NF-. The experiments were performed at pressures of 5 bar, 10 bar, 15 bar and 20 bar.
For NF90 membrane, a rejection of Na+ monovalent ion in 20 ppm solution was less than of Mg2+ (divalent) ion. Percentage rejections of 90% (Na+) and 98% (Mg2+) were achieved. NF- had rejection of 83% and 90% for Na+ and Mg2+, respectively. In the case of NF270, the membrane had rejection of 92% (Na+) and 94% (Mg2+), respectively.
At 100 ppm, all three membranes showed a decreasing trend in rejection while increasing pressure. For binary-solution mixture, Mg2+ ion still had the highest rejection compared to Na+ ion with about 94% and 85% on NF90 than on NF270 and NF-. The high rejection of divalent ion as compared to monovalent ion for charged solutes was due to solute size and electrostatic interaction between the membrane surface layer and the solute.
In the case of transition metal rejection studies, Pd2+ ion had an average of 90%, with Ni2+ ion ≈ 95% and Cu2+ ion ≈ 98% as single salts on NF90 compared to NF270 and NF-. However, as for binary and trinary solution mixture, the competition amongst ions was high, where Pd2+ ion rejection was ≈ 99,0%, while Ni2+ and Cu2+ ions was > 90% on NF90 and NF-. Therefore it was excluded from the tests. For the monovalent metal ions (Ag+ and Cu+), the rejection was > 90% in almost all concentrations mixtures. During membrane fouling evaluation, AgCl salt fouled the most, compared to other metal ions, forming a concentration polarization accumulation on the membrane surface for both 20 and 100 ppm solutions. This situation leads to cake layer formation which causes a flux decline, reduces membrane life time and lowers the rejection performance of NF membranes.
The aim of this study was to evaluate the performance of three commercial polymeric membranes (NF90, NF270 and NF-) during rejection of the metal
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Adjustable fluid and particle permeation through hydrogel composite membranesEhrenhofer, Adrian, Wallmersperger, Thomas 24 March 2021 (has links)
Membranes act as smart structures in respect to their permeation abilities. Control of particle and fluid permeation through a synthetic membrane can be achieved by using different effects like size-exclusion or electromagnetic interactions that occur between the particles and membrane pores. The simulation of controlled permeability provides an insight into the smart behavior of membranes for chemical signal processing, sensing interfaces or lab-on-a-chip devices. In the current work, we model the underlying physical processes on a microfluidic level using the engineer’s approach of laminar flow through pipes. Different pore geometries inside a composite membrane system consisting of a polyethylene terephthalate support membrane and a poly(N-isopropylacrylamide) hydrogel-layer are investigated. Simulations for different states of thermally induced pore opening are performed for free and blocked states. From the results we derive paradigms for the design of a membrane system for microfluidic cell-size profiling considering stimulus-range, pore shape and measurement setup.
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