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Dealloying and Formation of Nanoporosity in Noble-metal AlloysBryk, Mariusz Albert 21 March 2012 (has links)
Nanoporosity formation by selective dissolution of Ag-5 at. pct Au in perchloric acid has been investigated with regards to the mechanism of stress-corrosion cracking (SCC), film-induced cleavage in particular. It has been proven that dealloying of silver-gold systems containing low concentration of gold leads to the formation of a three dimensional nanoporous layer and that it can be carried out in a broad range of potentials and concentrations of a dealloying solution. Therefore, stress-corrosion cracking observed in these alloys may be caused, initiated or at least accompanied by the formation of nanoporosity resulting from dealloying. These results will have impact on the fabrication of cheaper nanomaterials where there is required large surface to volume ratio with gold as the outermost layer. Understanding the role of dealloying will also help us to design new materials of higher resistance against stress-corrosion cracking.
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Dealloying and Formation of Nanoporosity in Noble-metal AlloysBryk, Mariusz Albert 21 March 2012 (has links)
Nanoporosity formation by selective dissolution of Ag-5 at. pct Au in perchloric acid has been investigated with regards to the mechanism of stress-corrosion cracking (SCC), film-induced cleavage in particular. It has been proven that dealloying of silver-gold systems containing low concentration of gold leads to the formation of a three dimensional nanoporous layer and that it can be carried out in a broad range of potentials and concentrations of a dealloying solution. Therefore, stress-corrosion cracking observed in these alloys may be caused, initiated or at least accompanied by the formation of nanoporosity resulting from dealloying. These results will have impact on the fabrication of cheaper nanomaterials where there is required large surface to volume ratio with gold as the outermost layer. Understanding the role of dealloying will also help us to design new materials of higher resistance against stress-corrosion cracking.
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Synthesis and characterisation of size-selective nanoporous polymeric adsorbents for blood purificationWebb, Chris January 2011 (has links)
This thesis is concerned with the development and characterisation of polymeric nanoporous adsorbents to be used for blood purification. Current treatment methods for suffers of chronic renal failure are limited to haemodialysis, peritoneal dialysis and organ transplant. Organ transplant is the most efficient option however lack of donor organs mean that the majority of suffers rely on dialysis. Unfortunately both dialysis treatments are lacking when it comes to the removal of middle molecular weight molecules (MMs) (500 - 60000 Da) and the accumulation of these molecules has been attributed to a number of additional ailments suffered by those on long term dialysis. Sorbent augmented dialysis has been identified as a potential avenue to remove these MMs, an additional column would be introduced to the haemodialysis loop this would contain adsorbent particles to remove these unwanted molecules. Styrene-divinylbenzne copolymers have been identified as suitable for this task as they will non-specifically adsorb a wide range of molecules. One major concern with the introduction of a polymeric adsorbent is the potential removal of human serum albumin HSA from the patient's blood, this essential blood protein is present in very high concentrations typically 40g/l and this will potentially swamp the surface of any adsorbent. Fortunately HSA is a large blood protein (69kDa) and as such the method to combat this limitation as explored in this thesis is to tailor the pore structure of the polymeric adsorbent to size exclude albumin while retaining sufficient adsorption capacity to remove the MMs. To achieve these goals a number of polymeric adsorbents were generated using different porogens and degrees of crosslinking to control the porous structure. These adsorbents were analysed using a number of characterisation methods to assess their dry and swollen state porosities and molecular weight cut offs. Once a suitable material had been developed protein adsorption studies were carried out to confirm the size exclusion of HSA and the uptake of MMs.
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Exploration of novel materials in (bio)electrocatalysis: sensing in complex media and biocathodes for the CO2 reductionHernández Ibáñez, Naiara 14 December 2018 (has links)
Las etapas de transferencia electrónica o transferencia de carga involucradas en reacciones electroquímicas juegan un papel muy importante en un gran número de procesos biológicos y bioquímicos. Hoy en día, el interés de la comunidad científica se centra en explorar y entender exhaustivamente la naturaleza biológica y química de los fenómenos bioelectroquímicos que ocurren en los seres vivos, con el objeto de mimetizarlos en el laboratorio. Los procesos bioelectrocatalíticos presentan un amplio abanico de aplicaciones dirigidas al: (i) desarrollo de biorreactores electroquímicos para la mitigación de las emisiones de gases de efecto invernadero, la eliminación de contaminantes presentes en aguas residuales y urbanas, o la síntesis de productos con alto valor añadido para la industria, (ii) el desarrollo de biopilas y biobaterías, y (iii) el desarrollo de (bio)sensores electroquímicos con fines analíticos. Sin embargo, la implantación en el mercado de dispositivos basados en procesos biocatalíticos aún se enfrenta a varios desafíos, como son la robustez, la estabilidad a largo plazo, la reproducibilidad y la rentabilidad de producción en términos de materiales y fabricación de los dispositivos electroquímicos. La motivación de esta tesis doctoral es la de enfrentarse a algunos de los desafíos con los que se encuentra hoy en día la bioelectrocatálisis, para ello esta tesis doctoral se centra, principalmente en el estudio de nuevos materiales y mejora de rutas y estrategias bioelectrocatalíticas, con la finalidad de desarrollar dispositivos electroquímicos con aplicaciones analíticas y en la obtención de productos de valor añadido. En primer lugar esta tesis doctoral recoge el estudio y desarrollo de (bio)sensores electroquímicos para la determinación de lactato, L-cisteína, peróxido de hidrógeno y pH en medios biológicos complejos, y en segundo lugar estudia la bioelectrosíntesis de ácido fórmico a través de la reducción bioelectroquímica de dióxido de carbono.
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Adsorption dans un milieu carboné lamellaire nanoporeux : simulation Monte Carlo Grand Canonique, synthèse et caractérisation / Adsorption in a slit nanoporous carbon medium : Grand Canonical Monte Carlo simulation, synthesis and characterizationNguemalieu Kouetcha, Daniella 21 December 2017 (has links)
Les carbones désordonnés nanoporeux sont des supports efficaces pour le piégeage de polluants y compris à l’état de traces dans les eaux usées. Le phénomène d’adsorption à l’origine de la rétention des molécules est cependant complexe car dépendant d’une multitude de facteurs : structure, morphologie et charge de la surface carbonée d’une part,taille/forme et polarité de la molécule d’autre part, l’ensemble étant dépendant du pH et de la concentration. Pourune meilleure compréhension du phénomène, il est important de pouvoir étudier séparément certains paramètres.Dans la perspective d’étudier le phénomène d’adsorption en milieu aqueux sur des carbones nanoporeux à structure et morphologie modèle, des structures lamellaires nanoporeuses de type carbone turbostratique ont été générées numériquement en langage C++ avec le calcul de la fonction de distribution radiale ou de paires. L’adsorption gazeuse d’une molécule non polaire ou polaire puis de deux molécules polaires (H2O/CO2) et (H2O/C6H6O)a été simulée par la méthode Grand Canonique Monte Carlo sur ce support modèle (Isotherme d’adsorption,chaleur d’adsorption, densité des molécules adsorbées) en fonction de la température. Les temps de calcul ont été drastiquement diminués en développant des codes parallèles optimisés sous MPI C++. L’influence de la forme etde la distribution en taille des pores a été mise en évidence en simulant l’adsorption sur la structure d’un carbone activé déjà obtenue par reconstruction 3D de type RMC. Enfin, d’un point de vue expérimental, l’intercalation d’ions tetraalkylammonium par voie électrochimique dans des carbones lamellaires (HOPG et graphite) a été explorée en vue d’obtenir des carbones lamellaires nanoporeux (≈1 nm). La structure a été caractérisée par diffraction des rayons X. / Disordered nanoporous carbons are the good materials for capturing pollutants, including traces in wastewater. The phenomenon of adsorption at the origin of the retention of molecules is complex. However, depending on a multitude of factors : structure, morphology and loading of the carbonaceous surface, on the one hand, size/shapeand polarity of the molecule, on the other hand, the whole being dependent on pH and concentration. For a better understanding of the phenomenon, it is important to be able to study some parameters separately. In order to study the phenomenon of adsorption in aqueous medium on nanoporous carbons with structure and model morphology, nanoporous slit structures of turbostratic carbon type were generated numerically in C ++ language with thecalculation of the radial distribution function or pairs. The gas adsorption of a nonpolar or polar molecule and then oftwo polar molecules (H2O/CO2) and (H2O/C6H6O) was simulated by Grand Canonical Monte Carlo method on this model support (adsorption isotherm, adsorption heat, density of adsorbed molecules) as a function of temperature.The runtime has been drastically reduced by developing parallel codes optimized under MPI C ++. The influence of the shape and the pore size distribution was demonstrated by simulating the adsorption on the structure of an activated carbon already obtained by 3D reconstruction of the RMC type. Finally, from an experimental point of view, the intercalation of tetraalkylammonium ions electrochemically in slit carbons (HOPG and graphite) was explored in order to obtain nanoporous lamellar carbons ( ≈1 nm). The structure was characterized by X-ray diffraction.
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Caracterização e controle nanoestrutural da silica para fotonica produzida pelo metodo de aerosol em chama / Characterization and nanoestructural control of silican made by flame aerosol synthesisTomazi, Rodrigo Guevara 22 February 2006 (has links)
Orientador: Carlos Kenichi Suzuki / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica / Made available in DSpace on 2018-08-06T16:36:19Z (GMT). No. of bitstreams: 1
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Previous issue date: 2006 / Resumo: As preformas nanoestruturadas de sílica produzidas pelo método de aerosol em chama constituem-se em precursores estratégico para aplicações tecnológicas em fotônica, tais como fibras óticas especiais e lentes com elevada transmissividade ótica na região ultravioleta. Para conseguir tais propriedades torna-se de fundamental importância o controle das características nanoestruturais nas preformas de sílica, tais como a distribuição de tamanho de partículas e a nanoporosidade. Neste sentido, a técnica de SAXS foi utilizada no presente trabalho para a caracterização nanoestrutural das preformas de sílica, com o auxílio das técnicas de ARX, BET, MEV e FRX. Com o tratamento matemático dos dados de SAXS pelo método GNOM, foram obtidas curvas de distribuição de tamanhos de heterogeneidades com dimensões entre 1 e 100 nm e, através dos efeitos observados nestas heterogeneidades com: (i) variação da carga em amostras de preformas prensadas uniaxialmente, (ii) variação das condições de temperatura em preformas tratadas termicamente e (iii) incorporação de íons de érbio foi possível estabelecer um entendimento efetivo da nanoestrutura da sílica produzida por aerosol em chama sob o aspecto tanto quantitativo, quanto qualitativo. Este resultado possibilita a determinação e o controle da distribuição de tamanhos de nanopartículas e nanoporos, condições essenciais para o desenvolvimento e a produção de dispositivos avançados de sílica para fotônica / Abstract: The nanostructured silica preform made by the flame aerosol method represents a strategical precursor for technological applications in photonics, such as special optical fibers and high optical transmissivity lenses for ultraviolet radiation. In order to attain such a properties, it becomes particularly important to control the nanostructured characteristics of silica preforms, such as nanoporosity and particle size distribution. In this sense, SAXS technique has been used for the characterization of silica preforms in conjunction of several other techniques, ARX, BET, MEV and FRX. Using the mathematical treatment of SAXS data by the GNOM method, structural heterogeneities in the range 1-100 nm were measured. Additional nanoscale information was observed through various effects induced by: (i) impinging a mechanical stress, (ii) thermal treatment in controlled atmosphere and precise temperature control, (iii) erbium ions doping. It was then possible to attain an effective understanding of nanostructure properties of the high purity flame aerosol silica, both on qualitative and quantitative aspects. The present result allows the control of size and size distribution of nanoparticles and nanopores, that is essential for the development and the production of advanced silica devices for photonics / Mestrado / Materiais e Processos de Fabricação / Mestre em Engenharia Mecânica
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Synthesis and Characterization of Nanoporous Resin Particles for Water PurificationBorchert, Konstantin B.L. 03 May 2023 (has links)
Through progressive industrialization and the relentless consumption of natural raw materials, man is exerting a negative influence on his habitat. In particular, water as the basis of life and almost all processes of our economy is contaminated by various pollutants due to excessive use and insufficient purification. Here, oxyanions, heavy metal ions and organic pollutants pose a high risk to aquatic habitats and ultimately to humans. Due to insufficient removal, they also contribute to the loss of non-renewable raw materials for industrial cycles. Due to a mostly low effect concentration and potential interactions with diverse living organisms, the removal of many contaminants is extremely important to avoid further altering existing ecosystems.
Adsorption represents an energy-efficient method of removal using adsorbents suitable for this purpose. Highly cross-linked resin polymers such as poly(melamine-co-formaldehyde) (PMF) with its excellent chemical resistance, high number of functional groups and ease of preparation, represent promising starting points for adsorbents.
This dissertation describes the colloidal aqueous synthesis of nanoporous resin particles (e.g. PMF) by templating with SiO2 nanoparticles (SiO2 NPs), which are subsequently used to adsorb water pollutants. An overall goal of this work consists of elucidating the mechanism for particle and pore formation by systematically varying various synthesis parameters. Electron microscopy, N2-soprtion and particle size measurement are used to analyze the morphology, size and pore structure of the particles. Comprehensive investigations thus allow to determine the influence of each tested synthesis parameter on these properties.
A very important goal, especially for future large-scale applicability, is the colloidal production of uniform particles, which have both a high ordered porosity and particle diameters in the range of a few micrometers. This enables an application as a fixed-bed adsorber that can be flowed through. This goal is closely linked to the mechanistic elucidation of pore and particle formation in the synthesis.
The prepared nanoporous PMF particles were tested for various adsorption applications after their characterization. In order to obtain a comprehensive picture of the applicability of PMF particles, experiments with oxyanions, with pharmaceuticals as representatives of organic pollutants and with heavy metal ions will be carried out respectively. On the one hand, these experiments will focus on investigating the adsorption performance and mechanism of PMF with the respective pollutant. On the other hand, the influence of the changed porosity on the adsorption mechanism is investigated by using different particles of a varied synthesis parameter.
Sulfate and phosphate ions were investigated in the oxyanion class. Extremely high separation rates were demonstrated for both ions, significantly outperforming previous commercially available materials. In experiments concerning a potential selective adsorption and thus separation of both species, the PMF/SiO2 hybrid particles, in which the template had not yet been removed, showed a selective sulfate adsorption.
The immobilization of heavy metal ions was analyzed with special focus on the simultaneous separation of the Cu2+ ions and respective anions used here. Investigations of the adsorbent after the adsorption experiments by means of electron microscopy, X-ray scattering and electron spin resonance spectroscopy elucidated the adsorption mechanism, which had been insufficiently analyzed so far. Here, adsorption and surface-induced precipitation were identified as partially separate subprocesses, both of which are responsible for the separation of both metal and anions from solution. In adsorption experiments with the monovalent ions nitrate and chloride, a two-step uptake process was identified, which was mathematically described for the first time via a new adsorption isotherm.
In the scope of organic water pollutants, the separation of the pharmaceutical diclofenac is being tested. In particular, the adsorption of pharmaceuticals is an urgent issue due to their low effect concentration and ubiquity in surface and tap waters. Pharmaceutical separation using PMF has hardly been investigated worldwide despite its promising properties. In these experiments, particles templated with SiO2 NPs of different sizes and stabilized in different ways were tested. This resulted in pore systems that varied from each other especially in their accessibility of the pore system and in the diameter of the connecting channels between the main cavities. These characteristics significantly affected the adsorption capacity and separation rates in low concentration range.
A final goal is to synthesize a resin network that uses an equally highly functional triazine-based monomer instead of melamine. The monomer 2,4,6-tris(2,4,6-trihydroxyphenyl)-1,3,5-triazine (3PT) possesses nine hydroxyl groups each, whereby a polymer based on it should exhibit strongly modified adsorption properties compared to PMF. This monomer was used in an aqueous polymerization analogous to PMF to produce a previously unknown polymer network, which was designated P(3PT-F). Here, templating was omitted because the newly prepared material already exhibited intrinsic nanoporosity due to the size of the 3PT monomer. In subsequent adsorption experiments, very high separation rates were demonstrated for the toxic metal ions Pb2+, Cd2+ and Ni2+. In realistic initial concentrations, the contamination was reduced to drinking water quality in each case. P(3PT-F) also showed highly selective removal of Pb2+ over the common ions Ca2+, Mg2+, K+ and Fe2+. As fundamental evidence, reusability was also demonstrated by complete desorption with dilute HCl and subsequent re-adsorption without significant reduction in capacity.
Overall, starting from the fundamental study of PMF particle synthesis, a more general understanding of aqueous dispersion polymerization of hydrophobic resins was first derived and templating with hydrophilic SiO2 NPs was implemented. With the help of understanding the particle growth processes and interactions responsible for templating, the properties of the resulting particles could be controlled. Subsequently, the influence of the changed porosity in particular on the separation performance could be investigated in the adsorption studies. In addition, it was possible to analyze which interactions PMF enters into with the respective pollutant types. By replacing the monomer melamine with a hydroxyl-containing monomer, a novel resin polymer could be produced. With its altered porosity and reactivity, this can now serve as a new starting point for adsorption experiments with strongly altered adsorption performance, e.g. towards heavy metal ions.:Abstract 1
Kurzfassung 5
List of Publications 9
First-Author Publications 9
Co-Author Publications 10
Patent 12
Conference Proceedings 12
Oral Presentations 12
Poster 12
List of Figures 13
Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal: 14
Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal: 15
Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles: 16
SiO2 Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles: 18
Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions: 19
List of Tables 21
Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal: 21
Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal: 21
Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles: 22
SiO2 Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles: 22
Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions: 23
Abbreviations 25
Symbols 26
1. Introduction 1
2. Objectives and Experimental Design 5
3. Scientific Background 11
3.1. Poly(melamine-co-formaldehyde) 11
3.1.1. Polymerization Mechanism 11
3.1.2. Synthesis Strategies for the Preparation of Porous PMF Particles. 13
3.1.3. Fields of Application of PMF 13
3.2. Adsorption 15
3.2.1. Adsorption Isotherms and Mathematical Modeling 16
3.3. Surface Precipitation 20
4. Fundamentals of Instrumental Analytics 23
4.1. Gas Sorption Measurements 23
4.1.1. Determination of Pore Sizes 26
4.1.2. Determination of Specific Surface Area 27
4.2. Transmission Electron Microscopy 29
4.3. Inductively Coupled Plasma Optical Emission Spectroscopy 31
Results and Discussion 33
Chapter Overview 33
5. Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal 37
Graphical Abstract 37
Abstract 37
1. Introduction 38
2. Results and Discussion 39
2.1. Synthesis and Characterization of the PMF Particles 40
2.2. Sorption Experiments 47
3. Materials and Methods 54
3.1. Materials 54
3.2. Methods 54
3.3. Synthesis of the PMF Particles 56
3.4. Water Treatment Experiments 57
4. Conclusions 59
6. Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal 65
Graphical Abstract 65
Abstract 65
1. Introduction 66
2. Materials 68
3. Methods 68
3.1. Synthesis of the PMF particles 70
3.2. Water treatment experiments with diclofenac solution 72
3.3. Theoretical model 72
3. Results and Discussion 73
3.1. Synthesis and characterization of the PMF particles 74
3.2. Adsorption of Pharmaceutics 80
4. Conclusion 84
7. Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles 89
Graphical Abstract 89
Abstract 89
1. Introduction 90
2. Materials and methods 91
2.1. Materials 91
2.2. Synthesis of the Poly(melamine-co-formaldehyde) particles 92
2.3. Methods 93
2.4. Water treatment experiments 96
3. Results and discussion 97
3.1. Synthesis and characterization of the PMF particles 98
3.2. Cu2+ uptake experiments 102
3.3. Mechanism for Cu2+ and Anion Removal 115
3.4. Investigation of other heavy metal salts 116
4. Conclusions 117
8. SiO₂ Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles 121
Graphical Abstract 121
Abstract 121
1. Introduction 122
2. Materials and methods 123
2.1. Materials 123
2.2. Methods 124
2.3. Synthesis of the PMF particles 125
2.4. Water treatment experiments 128
2.5. Theoretical model 129
3. Results and Discussion 132
3.1. PMF-Std 133
3.2. Influence of the reaction mixture composition 136
3.3. Variation of the process parameters 140
3.4. Conclusion on the templating mechanism for PMF-Std 146
3.5. Acquiring µm-sized porous PMF particles for adsorption application 149
3.6. Adsorption experiments with K2Cr2O7 solution 151
4. Conclusion 155
9. Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions 161
Graphical Abstract 161
Abstract 161
1. Introduction 162
2. Materials and methods 163
2.1. Materials 163
2.2. Synthesis 164
2.3. Characterization 166
2.4. Batch adsorption experiments 169
2.5. Calculation and theoretical models 170
3. Results and discussion 172
3.1. Synthesis and characterization of the polymer particles 172
3.2. Adsorption experiments with Ni2+, Cd2+, and Pb2+ onto P(3PT-F)-3L 178
4. Conclusions 184
10. Conclusion and Outlook 191
Contribution to Publications 197
Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal 197
Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal 198
Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles 199
SiO₂ Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles 200
Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions 201
Danksagung 203
Appendix 205
References 207
Eidesstattliche Versicherung 217 / Durch fortschreitende Industrialisierung und den schonungslosen Verbrauch natürlicher Rohstoffe übt der Mensch negativen Einfluss auf seinen Lebensraum aus. Insbesondere Wasser als Grundlage des Lebens und fast aller Prozesse unserer Wirtschaft wird durch eine übermäßige Nutzung und unzureichende Reinigung mit diversen Schadstoffen kontaminiert. Hierbei stellen Oxyanionen, Schwermetallionen und organische Schadstoffe ein hohes Risiko für aquatische Lebensräume und letztendlich auch den Menschen dar. Durch unzureichende Entfernung tragen sie außerdem zum Verlust nicht-erneuerbarer Rohstoffe für industrielle Kreisläufe bei. Durch eine meist geringe Effektkonzentration und potentielle Wechselwirkungen mit diversen Lebewesen ist die Entfernung vieler Verunreinigungen extrem wichtig, um bestehende Ökosysteme nicht weiter zu verändern.
Adsorption stellt eine energieeffiziente Methode zur Entfernung dieser Schadstoffe durch hierfür geeignete Adsorbentien dar. Hochgradig vernetzte Harzpolymere wie Poly(melamin-co-formaldehyd) (PMF) stellen mit ihrer sehr hohen chemischen Beständigkeit, einer hohen Zahl funktioneller Gruppen und einfachen Herstellbarkeit einen vielversprechenden Ausgangspunkt für Adsorbentien dar.
Diese Dissertation beschreibt die kolloidale, wässrige Synthese nanoporöser Harzpartikel (z. B. PMF) durch eine Templatierung mit SiO2 Nanopartikeln (SiO2 NPs), welche anschließend zur Adsorption von Wasserschadstoffen eingesetzt werden. Ein übergeordnetes Ziel dieser Arbeit besteht aus der Aufklärung des Mechanismus zur Partikel- und Porenbildung durch systematische Variation verschiedener Syntheseparameter. Mittels Elektronenmikroskopie, N2-Sorption und Partikelgrößenmessung wird die Morphologie, Größe und Porenstruktur der Partikel analysiert. Umfassende Untersuchungen ermöglichen somit, den Einfluss der einzelnen getesteten Syntheseparameter auf diese Eigenschaften zu bestimmen.
Ein sehr wichtiges Ziel, besonders für eine zukünftige großtechnische Anwendbarkeit, ist dabei die kolloidale Herstellung uniformer Partikel, welche sowohl eine hohe geordnete Porosität als auch Partikeldurchmesser im Bereich einiger Mikrometer aufweisen. Dies ermöglicht einen Einsatz als durchströmbaren Festbett-Adsorber. Dieses Ziel ist eng mit der mechanistischen Aufklärung der Poren- und Partikelbildung in der Synthese verknüpft.
Die hergestellten nanoporösen PMF-Partikel wurden nach ihrer Charakterisierung für verschiedene Adsorptionsanwendungen getestet. Um ein umfassendes Bild über die Einsetzbarkeit von PMF-Partikeln zu erhalten, sollen jeweils Versuche mit Oxyanionen, mit Schwermetallionen und mit Pharmazeutika als Vertreter organischer Schadstoffe durchgeführt werden. Bei diesen Versuchen steht zum einen die Untersuchung der Adsorptionsleistung und des Adsorptionsmechanismus des jeweiligen Schadstoffes an PMF im Vordergrund. Zum anderen wird durch die Verwendung verschiedener Partikel, bei welchen ein einzelner Syntheseparameter variiert wurde, der Einfluss der veränderten Porosität auf den Adsorptionsmechanismus untersucht.
Sulfat- und Phosphationen wurden in der Klasse der Oxyanionen untersucht. Für beide Ionen wurden extrem hohe Abtrennraten nachgewiesen, welche bisherige kommerziell erhältliche Materialien signifikant übertraf. In Versuchen hinsichtlich einer potentiellen selektiven Adsorption und somit Trennung beider Spezies, zeigten die PMF/SiO2-Hybridpartikel, bei welchen das Templat noch nicht entfernt wurde, eine selektive Sulfatadsorption.
Die Immobilisierung von Schwermetallionen wurde mit besonderem Fokus auf die gleichzeitig auftretende Abtrennung der dafür verwendeten Cu2+-Ionen und jeweiliger Anionen analysiert. Durch Untersuchungen des Adsorbens nach den Adsorptionsversuchen mittels Elektronenmikroskopie, Röntgenstreuung und Elektronenspinresonanz-Spektroskopie wurde der bisher unzureichend analysierte Adsorptionsmechanismus aufgeklärt. Hierbei wurden Adsorption und oberflächeninduzierte Fällung als separate Teilprozesse identifiziert, welche beide jeweils für die Abscheidung von sowohl Metall- als auch Anionen aus der Lösung verantwortlich sind. Bei Adsorptionsversuchen mit den einwertigen Ionen Nitrat und Chlorid wurde ein zweistufiger Prozess identifiziert, welcher erstmals über eine neue Adsorptionsisotherme mathematisch beschrieben wurde.
Im Bereich organischer Wasserschadstoffe wird die Abtrennung des Pharmazeutikums Diclofenac getestet. Insbesondere die Adsorption von Pharmazeutika stellt aufgrund von deren geringen Effektkonzentration und Allgegenwärtigkeit in Oberflächen- und Leitungswässern ein dringliches Thema dar. Die Pharmazeutika-Abtrennung mittels PMF wurde trotz seiner vielversprechenden Eigenschaften weltweit bisher kaum untersucht. Im Rahmen dieser Versuche wurden Partikel getestet, welche mit unterschiedlich großen und unterschiedlich stabilisierten SiO2 NPs templatiert wurden. Dadurch entstanden Porensysteme, die besonders in derer Zugänglichkeit ihres Porensystems und in dem Durchmesser der Verbindungskanäle zwischen den Hauptkavitäten voneinander variierten. Diese Eigenschaften wirkten sich signifikant auf die Adsorptionskapazität und die Abtrennraten im niedrigen Konzentrationsbereich aus.
Ein abschließendes Ziel ist die Synthese eines Harznetzwerkes, welches statt Melamin auf einem ebenso hochfunktionellen, triazinbasierten Monomer basiert. Das Monomer 2,4,6-Tris(2,4,6-trihydroxyphenyl)-1,3,5-triazin (3PT) besitzt jeweils neun Hydroxylgruppen, wodurch ein darauf basierendes Polymer stark veränderte Adsorptionseigenschaften gegenüber PMF aufweisen soll. Mit diesem Monomer wurde in einer analog zu PMF durchgeführten wässrigen Polymerisation ein bisher unbekanntes Polymernetzwerk hergestellt, welches als P(3PT-F) bezeichnet wurde. Hierbei wurde auf Templatierung verzichtet, da das neu hergestellte Material bereits intrinsische Nanoporosität durch die Größe des verwendeten 3PT-Monomers aufwies. In anschließenden Adsorptionsversuchen wurden sehr hohe Abtrennraten für die toxischen Metallion Pb2+, Cd2+ und Ni2+ nachgewiesen. In realistischen Ausgangskonzentrationen wurde die Kontamination mit diesen Ionen jeweils auf Trinkwasserqualität reduziert. P(3PT-F) zeigte außerdem eine sehr selektive Abtrennung von Pb2+ gegenüber den häufig vorkommenden Ionen Ca2+, Mg2+, K+ und Fe2+. Als grundlegender Beweis konnte eine Wiederverwendbarkeit durch die vollständige Desorption mit verdünnter HCl gezeigt werden und eine anschließende erneute Adsorption ohne signifikante Verringerung der Kapazität.
Insgesamt wurde ausgehend von der grundlegenden Untersuchung der PMF-Partikelsynthese erst ein generelleres Verständnis der wässrigen Dispersionspolymerisation hydrophober Harze abgeleitet und die Templatierung mit hydrophilen SiO2 NPs implementiert. Mithilfe des Verständnisses der Partikelwachstumsprozesse und der Wechselwirkungen, welche für die Templatierung verantwortlich sind, konnten die Eigenschaften der entstehenden Partikel gesteuert werden. Im Rahmen der Adsorptionsuntersuchungen konnte anschließend der Einfluss insbesondere der veränderten Porosität auf die Abtrennleistung untersucht werden. Außerdem konnte analysiert werden, welche Wechselwirkungen PMF mit den jeweiligen Schadstoffarten eingeht. Durch den Austausch des Monomers Melamin gegen das hydroxylhaltiges Monomer 3PT konnte ein neuartiges Harzpolymer hergestellt werden. Dieses kann mit seiner veränderten Porosität und Reaktivität nun als neuer Ausgangspunkt für Adsorptionsexperimente mit stark veränderter Adsorptionsleistung z. B. gegenüber Schwermetallionen dienen.:Abstract 1
Kurzfassung 5
List of Publications 9
First-Author Publications 9
Co-Author Publications 10
Patent 12
Conference Proceedings 12
Oral Presentations 12
Poster 12
List of Figures 13
Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal: 14
Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal: 15
Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles: 16
SiO2 Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles: 18
Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions: 19
List of Tables 21
Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal: 21
Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal: 21
Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles: 22
SiO2 Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles: 22
Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions: 23
Abbreviations 25
Symbols 26
1. Introduction 1
2. Objectives and Experimental Design 5
3. Scientific Background 11
3.1. Poly(melamine-co-formaldehyde) 11
3.1.1. Polymerization Mechanism 11
3.1.2. Synthesis Strategies for the Preparation of Porous PMF Particles. 13
3.1.3. Fields of Application of PMF 13
3.2. Adsorption 15
3.2.1. Adsorption Isotherms and Mathematical Modeling 16
3.3. Surface Precipitation 20
4. Fundamentals of Instrumental Analytics 23
4.1. Gas Sorption Measurements 23
4.1.1. Determination of Pore Sizes 26
4.1.2. Determination of Specific Surface Area 27
4.2. Transmission Electron Microscopy 29
4.3. Inductively Coupled Plasma Optical Emission Spectroscopy 31
Results and Discussion 33
Chapter Overview 33
5. Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal 37
Graphical Abstract 37
Abstract 37
1. Introduction 38
2. Results and Discussion 39
2.1. Synthesis and Characterization of the PMF Particles 40
2.2. Sorption Experiments 47
3. Materials and Methods 54
3.1. Materials 54
3.2. Methods 54
3.3. Synthesis of the PMF Particles 56
3.4. Water Treatment Experiments 57
4. Conclusions 59
6. Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal 65
Graphical Abstract 65
Abstract 65
1. Introduction 66
2. Materials 68
3. Methods 68
3.1. Synthesis of the PMF particles 70
3.2. Water treatment experiments with diclofenac solution 72
3.3. Theoretical model 72
3. Results and Discussion 73
3.1. Synthesis and characterization of the PMF particles 74
3.2. Adsorption of Pharmaceutics 80
4. Conclusion 84
7. Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles 89
Graphical Abstract 89
Abstract 89
1. Introduction 90
2. Materials and methods 91
2.1. Materials 91
2.2. Synthesis of the Poly(melamine-co-formaldehyde) particles 92
2.3. Methods 93
2.4. Water treatment experiments 96
3. Results and discussion 97
3.1. Synthesis and characterization of the PMF particles 98
3.2. Cu2+ uptake experiments 102
3.3. Mechanism for Cu2+ and Anion Removal 115
3.4. Investigation of other heavy metal salts 116
4. Conclusions 117
8. SiO₂ Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles 121
Graphical Abstract 121
Abstract 121
1. Introduction 122
2. Materials and methods 123
2.1. Materials 123
2.2. Methods 124
2.3. Synthesis of the PMF particles 125
2.4. Water treatment experiments 128
2.5. Theoretical model 129
3. Results and Discussion 132
3.1. PMF-Std 133
3.2. Influence of the reaction mixture composition 136
3.3. Variation of the process parameters 140
3.4. Conclusion on the templating mechanism for PMF-Std 146
3.5. Acquiring µm-sized porous PMF particles for adsorption application 149
3.6. Adsorption experiments with K2Cr2O7 solution 151
4. Conclusion 155
9. Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions 161
Graphical Abstract 161
Abstract 161
1. Introduction 162
2. Materials and methods 163
2.1. Materials 163
2.2. Synthesis 164
2.3. Characterization 166
2.4. Batch adsorption experiments 169
2.5. Calculation and theoretical models 170
3. Results and discussion 172
3.1. Synthesis and characterization of the polymer particles 172
3.2. Adsorption experiments with Ni2+, Cd2+, and Pb2+ onto P(3PT-F)-3L 178
4. Conclusions 184
10. Conclusion and Outlook 191
Contribution to Publications 197
Mesoporous Poly(Melamine-co-Formaldehyde) Particles for Efficient and Selective Phosphate and Sulfate Removal 197
Tuning the Pore Structure of Templated Mesoporous Poly(melamine-co-formaldehyde) Particles toward Diclofenac Removal 198
Adsorption vs. Surface Precipitation of Cu²+ onto Porous Poly(melamine-co-formaldehyde) Particles 199
SiO₂ Nanospheres as Surfactant and Template in Aqueous Dispersion Polymerizations Yielding Nanoporous Resin Particles 200
Waterborne Phenolic, Triazine-Based Porous Polymer Particles for the Removal of Nickel, Cadmium, and Lead Ions 201
Danksagung 203
Appendix 205
References 207
Eidesstattliche Versicherung 217
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