Supramolecular structures of dendronized polymers and DNA on solid substrates

Gössl, Illdiko Maria

30 June 2003

Komplexe aus entgegengesetzt geladenen Polyelektrolyten haben sowohl in der Biologie als auch in den Materialwissenschaften eine große Bedeutung. Im Mittelpunkt des Interesses stehen besonders die Kondensation der DNA in vitro, die Struktur des Nukleosoms im Zellkern, nicht-virale Systeme zur Transfektion von DNA in Zellen oder der Vorgang der layer-by-layer Adsorption. Verschiedene Theorien befassen sich mit den treibenden Kräften solcher Komplexbildungen. Allerdings standen experimentelle Untersuchungen auf diesem Gebiet bisher noch aus. Dieser Arbeit liegt die Fragestellung zu Grunde, ob es mit Hilfe der Rasterkraftmikroskopie möglich ist, die Struktur einzelner Polyelektrolytkomplexe, bestehend aus den beiden Polyelektrolyten DNA und dendronisierten Polymer, aufzuklären und ihre Komplexbildung zu untersuchen. Die Komplexe bildeten sich in Lösung und wurden anschließend auf einer unbeschichteten oder mit positiven Polymeren beschichteten Glimmeroberfläche adsorbiert. Auf der positiv beschichteten Glimmeroberfläche hafteten DNA-dendronisierte Polymer Komplexe mit einem Ladungsverhältnis von 1:1 bis 1:0.7 (DNA:dendronisiertes Polymer). Anhand der hochaufgelösten rasterkraftmikroskopischen Aufnahmen wurde ein Modell entwickelt, das die Umwicklung der DNA um das dendronisierte Polymer beschreibt. Der DNA-DNA Abstand ergab sich zu (2.30 ± 0.27) nm für den Komplex mit DNA und zweiter Generation dendronisierter Polymere und zu (2.16 ± 0.27) nm mit vierter Generation. Die theoretische Vorhersage der Überladung der Komplexe konnte experimentell bestätigt werden. Mit Hilfe der Rasterkraftmikroskopie konnte überdies der Einfluss des Salzgehaltes der Lösung auf die Bildung der Komplexe mit DNA und zweiter Generation dendronisierter Polymere untersucht werden. Wie man anhand des Zusammenwirkens von elektrostatischen Kräften und entropischen Wechselwirkungen bei der Adsorption von Polyelektrolyten vorhersagen kann, durchlief der DNA-DNA Abstand ein Minimum bei ansteigendem Salzgehalt. Bei sehr hohem Salzgehalt (2.4 M NaCl) konnte das Ablösen der DNA von dem Komplex beobachtet werden. Die untersuchten DNA/dendroniserten Polymer Komplexe bilden ein neues Modellsystem, mit dem einzelne Polyelektrolyt-Wechselwirkungen direkt untersucht werden können. Ein Vergleich der experimentellen Daten mit den vorhandenen Theorien zeigte, dass der Prozess des Überladens weitgehend durch elektrostatische Wechselwirkung zwischen den beiden Polyelektrolyten beschrieben werden kann. Sowohl entropische Beiträge als auch die Biegeenergie der umwickelnden DNA sind vernachlässigbar. Basierend auf diesen Ergebnissen können neue Trägerstrukturen für effizientere nicht-virale DNA-Transfektionssysteme entwickelt werden. / Complexes of oppositely charged polyelectrolytes play an important role in both biology and material science, for instance DNA condensation in vitro, nucleosomal structure, non-viral gene transfection systems as well as layer-by-layer adsorption. Although there are theories predicting overcharging of polyelectrolyte complexes, the driving forces are still under debate and systematic experimental studies on single polyelectrolytes remain challenging. Therefore the question arose if it is possible to analyze single polyelectrolyte complexes, using DNA and dendronized polymers, with the scanning force microscope in order to investigate the complexation in detail. For the complex analysis, the polyelectrolytes were allowed to interact in solution and then to adsorb on negatively charged mica or on mica coated with a positively charged polymer. Scanning force microscopy was used to investigate the adsorbed species. DNA/dendronized polymer complexes of charge ratio of 1/1 through 1/0.7 adsorbed on mica coated with a positively charged polymer. The analysis of high resolution molecular images indicated that DNA wraps around the dendronized polymer with an estimated pitch of (2.30 ± 0.27) nm and (2.16 ± 0.27) nm for dendronized polymers of generation two and four, respectively. In the proposed model the polyelectrolyte with the smaller linear charge density is wrapped around the more highly charged dendronized polymer, resulting in a negatively overcharged complex. This overcharging is consistent within recent theories of spontaneous overcharging of complexes of one polyelectrolyte wrapping around the other. Using the complex of DNA and dendronized polymers of second generation, the influence of monovalent salt concentration on the molecular structure was studied. By increasing the salt concentration the pitch showed a minimum as predicted by the interplay of electrostatic forces and entropic interactions of polyelectrolyte adsorption. At high salt concentration (2.4 M NaCl) the release of DNA from the complex can be observed. The results showed that the DNA/dendronized polymer system can be used as a new, high potential model system to investigate single polyelectrolyte interactions. With regard to recent theories, the experimental results indicate that the overcharging of the complex is mainly driven by electrostatic forces whereas contributions of counterion entropy and bending energy seem to be negligible. This understanding may be useful for the design of single polyelectrolyte complexes for non-viral gene delivery systems and might help to optimize the transfection efficiency based on the structure of the vector system.

DNA Komplex

Polyelektrolytkomplex

Einfluss des Salzgehaltes

Rasterkraftmikroskopie

DNA complex

polyelectrolyte complex

influence of salt concentration

scanning force microscopy

530 Physik

29 Physik, Astronomie

UV 9500

ddc:530

Contributions théoriques à l'étude des polymères aux interfaces

MANGHI, Manoel

27 June 2002

Cette thèse s'inscrit dans le cadre général de l'étude des propriétés statistiques de chaînes polymères aux interfaces. Il s'agit d'un travail théorique qui a pour but de relier les propriétés macroscopiques de l'interface (épaisseur, quantité de monomères adsorbées, tension de surface) à l'organisation microscopique des chaînes. La couche de polymères est décrite en termes de boucles et de queues formées par les polymères adsorbés, en combinant la physique statistique d'une population de boucles de différentes tailles et les lois d'échelle. Tout d'abord, un lien formel est établi entre cette approche phénoménologique et les premiers principes de la physique statistique des polymères en montrant que cette modélisation est une théorie variationnelle. Puis, cette théorie est appliquée au problème de la tension de surface de liquides polymères (solutions semi-diluées et polymères fondus). Les variations de la tension de surface avec la masse moléculaire des chaînes, la température et la fraction volumique dans la solution sont alors déduites. La comparaison de ces résultats avec des mesures expérimentales de tension de surface, trouvées dans la littérature, met en lumière le rôle de la tensio-activité des bouts de chaînes et celui de l'entropie associée à la distribution des boucles. Cette théorie est ensuite étendue au cas de l'adsorption de polyélectrolytes sur une surface de charge opposée, à partir d'une solution semi-diluée. La structure de la couche est décrite analytiquement et l'existence d'une couche extérieure formée de grandes boucles induit une inversion de charge. Enfin, sont abordées la question de l'influence de la géométrie concave sur la structure d'une brosse de polymères et l'étude des connecteurs polymères mobiles. Les propriétés adhésives des jonctions formées par ces derniers dépendent alors fortement de la géométrie des objets connectés et des caractéristiques des polymères.

[PHYS:MPHY] Physics/Mathematical Physics

polymere

interface

adsorption

tension de surface

polyelectrolyte

lois d'echelle

brosse de polymeres

champ moyen

connecteur

pont adhesif

Interaction between Crosslinked Polyelectrolyte Gels and Oppositely Charged Surfactants

Nilsson, Peter

January 2007

<p>The interactions between anionic, crosslinked gels and cationic surfactants have been investigated. When exposed to oppositely charged surfactant, the gel collapses into a dense complex of polyion and micelles. During deswelling, the gel phase separates into a micelle-rich, collapsed surface phase, and a swollen, micelle-free core, both still part of the same network. As more surfactant is absorbed, the surface phase grows at the expense of the core, until the entire gel has collapsed. Polyacrylate (PA) gels with dodecyl- (C₁₂TAB), and cetyltrimethylammonium bromide (C₁₆TAB), as well as hyaluronate gels with cetylpyridinium chloride, have been studied. </p><p>Kinetic experiments have been performed on macro- as well as microgels, using micromanipulator assisted light microscopy for the latter. A surfactant diffusion controlled deswelling model has been employed to describe the deswelling. The deswelling kinetics of PA microgels have been shown to be controlled by surfactant diffusion through the stagnant layer surrounding the gel, as the surface phase is relatively thin for the major part of the deswelling. For macroscopic PA gels the surface phase is thicker, and the kinetics with C₁₂TAB were therefore also influenced by diffusion through the surface phase, while for C₁₆TAB they were dominated by it. </p><p>Relevant parameters have also been determined using equilibrium experiments. An irregular, balloon-forming deswelling pattern, mainly found for macrogels, as well as unexpectedly long lag times and slow deswelling for microgels, are reported and discussed. </p><p>The microstructure of fully collapsed PA/C₁₂TAB complexes has been studied using small-angle X-ray scattering. A cubic <i>Pm3n</i> structure was found at low salt concentration, which melted into a disordered micellar phase as the salt concentration was increased. Further increasing the salt concentration dissolved the micelles, resulting in no ordering.</p>

Pharmaceutical chemistry

gel

polyelectrolyte

surfactant

deswelling

kinetics

phase separation

volume transition

ion-exchange

diffusion

liquid crystal

SAXS

cubic Pm3n

Farmaceutisk kemi

Charged polymer-macroion complexes

Boroudjerdi, Hoda

January 2005

This work explores the equilibrium structure and thermodynamic phase behavior of complexes formed by charged polymer chains (polyelectrolytes) and oppositely charged spheres (macroions). Polyelectrolyte-macroion complexes form a common pattern in soft-matter physics, chemistry and biology, and enter in numerous technological applications as well. From a fundamental point of view, such complexes are interesting in that they combine the subtle interplay between electrostatic interactions and elastic as well as entropic effects due to conformational changes of the polymer chain, giving rise to a wide range of structural properties. This forms the central theme of theoretical studies presented in this thesis, which concentrate on a number of different problems involving strongly coupled complexes, i.e. complexes that are characterized by a large adsorption energy and small chain fluctuations. <br><br> In the first part, a global analysis of the structural phase behavior of a single polyelectrolyte-macroion complex is presented based on a dimensionless representation, yielding results that cover a wide range of realistic system parameters. Emphasize is made on the interplay between the effects due to the polyelectrolytes chain length, salt concentration and the macroion charge as well as the mechanical chain persistence length. The results are summarized into generic phase diagrams characterizing the wrapping-dewrapping behavior of a polyelectrolyte chain on a macroion. A fully wrapped chain state is typically obtained at intermediate salt concentrations and chain lengths, where the amount of polyelectrolyte charge adsorbed on the macroion typically exceeds the bare macroion charge leading thus to a highly overcharged complex. <br><br> Perhaps the most striking features occur when a single long polyelectrolyte chain is complexed with many oppositely charged spheres. In biology, such complexes form between DNA (which carries the cell's genetic information) and small oppositely charged histone proteins serving as an efficient mechanism for packing a huge amount of DNA into the micron-size cell nucleus in eucaryotic cells. The resultant complex fiber, known as the chromatin fiber, appears with a diameter of 30~nm under physiological conditions. Recent experiments indicate a zig-zag spatial arrangement for individual DNA-histone complexes (nucleosome core particles) along the chromatin fiber. A numerical method is introduced in this thesis based on a simple generic chain-sphere cell model that enables one to investigate the mechanism of fiber formation on a systematic level by incorporating electrostatic and elastic contributions. As will be shown, stable complex fibers exhibit an impressive variety of structures including zig-zag, solenoidal and beads-on-a-string patterns, depending on system parameters such as salt concentration, sphere charge as well as the chain contour length (per sphere). The present results predict fibers of compact zig-zag structure within the physiologically relevant regime with a diameter of about 30~nm, when DNA-histone parameters are adopted. <br><br> In the next part, a numerical method is developed in order to investigate the role of thermal fluctuations on the structure and thermodynamic phase behavior of polyelectrolyte-macroion complexes. This is based on a saddle-point approximation, which allows to describe the experimentally observed reaction (or complexation) equilibrium in a dilute solution of polyelectrolytes and macroions on a systematic level. This equilibrium is determined by the entropy loss a single polyelectrolyte chain suffers as it binds to an oppositely charged macroion. This latter quantity can be calculated from the spectrum of polyelectrolyte fluctuations around a macroion, which is determined by means of a normal-mode analysis. Thereby, a stability phase diagram is obtained, which exhibits qualitative agreement with experimental findings. <br><br> At elevated complex concentrations, one needs to account for the inter-complex interactions as well. It will be shown that at small separations, complexes undergo structural changes in such a way that positive patches from one complex match up with negative patches on the other. Furthermore, one of the polyelectrolyte chains may bridge between the two complexes. These mechanisms lead to a strong inter-complex attraction. As a result, the second virial coefficient associated with the inter-complex interaction becomes negative at intermediate salt concentrations in qualitative agreement with recent experiments on solutions of nucleosome core particles. / In dieser Arbeit werden Gleichgewichtsstrukturen und die thermodynamischen Phasen von Komplexen aus geladenen Polymeren (Polyelektrolyten) und entgegengesetzt geladenen Kugeln (Makroionen) untersucht. Polyelektrolyt-Makroion-Komplexe bilden ein grundlegendes und wiederkehrendes Prinzip in der Physik weicher Materie sowie in Chemie und Biologie. In zahlreichen technologischen Prozessen finden sich ebenfalls Anwendungsbeispiele für derartige Komplexe. Zusätzlich zu ihrem häufigen Auftreten sind sie aufgrund ihrer Vielfalt von strukturellen Eigenschaften von grundlegendem Interesse. Diese Vielfalt wird durch ein Zusammenspiel von elektrostatischen Wechselwirkungen sowie elastischen und entropischen Effekten aufgrund von Konformationsänderungen in der Polymerkette bedingt und bildet das zentrale Thema der theoretischen Studien, die mit dieser Arbeit vorgelegt werden. Verschiedene Strukturen und Prozesse, die stark gekoppelte Komplexe beinhalten - das sind solche, für die eine hohe Adsorptionsenergie und geringe Fluktuationen in den Polymerketten charakteristisch sind -, bilden das Hauptthema der Arbeit. <br><br> Basierend auf einer dimensionslosen Darstellung wird im ersten Teil der Arbeit in einer umfassenden Analyse das strukturelle Phasenverhalten einzelner Polyelektrolyt-Makroion-Komplexe behandelt. Der Schwerpunkt wird hier auf das Wechselspiel zwischen Effekten aufgrund der Polyelektrolytkettenlänge, ihrer mechanischen Persistenzlänge, der Salzkonzentration und der Ladung des Makroions gelegt. Die Ergebnisse werden in allgemeinen Phasendiagrammen zusammengestellt, das das Aufwickeln-Abwickeln-Verhalten der Polyelektrolytkette auf einem Makroion beschreibt. Ein Zustand mit komplett aufgewickelter Kette tritt typischerweise bei mittleren Salzkonzentrationen und Kettenlängen auf; häufig ist hier die auf dem Makroion adsorbierte Gesamtladung des Polyelektrolyts größ er als die Ladung des nackten Makroions, d.h. es findet in hohem Grad Ladungsinversion statt. <br><br> Äußerst bemerkenswerte Eigenschaften treten auf, wenn eine einzelne lange Polyelektrolytkette viele, ihr entgegengesetzt geladene Kugeln komplexiert. In biologischen Systemen findet man solche Komplexe zwischen DNS, die die genetische Information einer Zelle trägt, und kleinen, entgegengesetzt geladenen Histonproteinen. Diese Komplexe dienen als effizienter Mechanismus, die groß e Menge an DNS im Mikrometer-groß en Zellkern eukaryotischer Zellen zu komprimieren. Die dadurch erhaltene komplexe Faser, eine Chromatinfaser, hat unter physiologischen Bedingungen einen Durchmesser von nur etwa 30~nm. Neue Experimente haben gezeigt, dass eine räumliche Zickzack-Anordnung einzelner DNA-Histon-Komplexe entlang der Chromatinfaser vorliegt. In der hier vorgelegten Arbeit wird eine numerische Methode vorgestellt, die auf einem einfachen Ketten-Kugel-Zell-Modell basiert und die die systematische Untersuchung des Mechnismus zur Faserbildung ermöglicht, wobei sowohl elektrostatische als auch elastische Wechselwirkungen berücksichtigt werden. Es wird gezeigt, dass stabile Komplexfasern in Abhängigkeit von der Salzkonzentration, der Kugelladung und der Kettenkonturlänge eine Vielfalt von Strukturen aufweisen, darunter Zickzack-, Solenoid- und Perlenkettenformen. Für physiologisch relevante Bedingungen werden mit dieser Methode für DNA-Histon-Komplexe Fasern kompakter Zickzack-Struktur mit einem Durchmesser von etwa 30~nm erhalten. <br><br> Im folgenden Teil wird eine numerische Methode entwickelt, um den Einfluss thermischer Fluktuationen auf Struktur und thermodynamisches Phasenverhalten der Polyelektrolyt-Makroion-Komplexe zu untersuchen. Basierend auf der Sattelpunktsnäherung werden die experimentell beobachteten Reaktionsgleichgewichte in verdünnten Lösungen von Polyelektrolyten und Makroionen systematisch beschrieben. Das Gleichgewicht ist durch einen Verlust an Entropie für die einzelne Polyelektrolytkette durch die Bindung an das entgegengesetzt geladene Makroion gekennzeichnet. Diese Größ e wurde aus dem Spektrum der Polyelektrolytfluktuationen um das Makroion erhalten und mittels einer Analyse der Normalmoden berechnet. Hierüber wird ein Phasendiagramm zur Stabilität der Komplexe erhalten, das qualitativ gute Übereinstimmungen mit experimentellen Ergebnissen aufweist. <br><br> Bei höheren Komplexkonzentrationen müssen auch die Wechselwirkungen zwischen den Komplexen berücksichtigt werden. Es wird gezeigt, dass sich die Struktur der Komplexe bei kleinen Abständen so ändert, dass positiv geladene Bereiche eines Komplexes mit negativ geladenen auf einem Nachbarkomplex räumlich korrelieren. Weiterhin können einzelne Polyelektrolytketten als verbrückendes Element zwischen zwei Komplexen dienen. Dieser Mechanismus führt zu starker effektiver Anziehung zwischen den Komplexen. In Übereinstimmung mit kürzlich durchgeführten Experimenten ist als Folge davon der zweite Virialkoeffizient der Wechselwirkung zwischen Komplexen bei mittleren Salzkonzentrationen negativ.

Biopolymere

Histon-DNS-Komplex

DNS-Bindungsproteine

DNS

Chromatin

Kolloides System

Kolloidphysik

Polyelektrolyt

geladene Systeme

Theorie

Polyelektrolytkomplexe

Chromatin

Histone-DNA Complexes

Charged Systems

Polyelectrolyte Complexes

Physics

New Techniques for Continuous Chemical Analysis in the Pulp&amp;Paper Industry

Rice, Matthew

January 2001

This thesis presents some new techniques that were developedfor continuous chemical analysis of a paper furnish. First, ageneral background is presented, covering topics from theorigins of papermaking to present day. A short introduction topapermaking chemistry and a variety of presently availableon-line chemical analysers and measurement strategies are alsodiscussed. A method is described for the continuous fractionation of apaper furnish containing coarse fibres (&gt;10µm) in orderto obtain a sample for analytical purposes (Paper I). Aconsistent sample, containing a representative fraction of thedissolved and colloidal substances (DCS) present in the bulkfurnish, was achieved by preventing cake formation on a filtersurface. A combination of turbulent flow above a membranefilter, while continuously withdrawing a relatively low samplevolume, were key factors in the prevention of filterfouling. For the continuous flow-extraction of DCS, a technique isdescribed whereby the extracting solvent was injected at a highvelocity into a continuous flow of analyte (Paper II).Comparison with conventional flow extraction showed anextraction enhancement of up to 9 times for colloidaltriglycerides. To achieve a continuous determination of chemicalsubstances, a real-time fully automated colorimetric titrationapparatus was developed (Paper III&amp;IV). This was achievedby using a series of micro-machined mixing channels for thecontinuous flow of analyte, with a sequence of detection unitsand titrant addition points along the flowpath (Paper III). Afuzzy logiccontroller was implemented to continuously adaptfor changes in the sample concentration, providing thepossibility of titrating over two orders of magnitude in sampleconcentration with minimal loss of accuracy (Paper IV). Also, a system is presented whereby the filtration apparatus(Paper I) is combined with the titration device (Paper III&amp;IV) in order to continuously determine total charge (orcolloidal charge) of a paper furnish in real-time (Paper V).This was achieved by utilising a back-titration approach andselected examples are presented showing the dynamicinteractions between wood fibres and polyelectrolyte adsorptionat various conditions of pH and polyelectrolyte molecularweight. Finally, some suggestions for a more comprehensive wet-endchemical monitoring platform are discussed and the role of thepresent work in evaluated in this context. <b>Keywords:</b>Chemical monitoring, continuous flowextraction, cross-flow filtration, dissolved and colloidalcomponents, fuzzy-logic control, on-line system, pitchanalysis, polyelectrolyte titration, process control, samplework-up, titrimetric analysis.

Chemical monitoring

continuous flow extraction

cross-flow filtration

dissolved and colloidal components

fuzzy-logic control

on-line system

pitch analysis

polyelectrolyte titration

process control

sample work-up

titrimetric analysis

Interaction between Crosslinked Polyelectrolyte Gels and Oppositely Charged Surfactants

Nilsson, Peter

January 2007

The interactions between anionic, crosslinked gels and cationic surfactants have been investigated. When exposed to oppositely charged surfactant, the gel collapses into a dense complex of polyion and micelles. During deswelling, the gel phase separates into a micelle-rich, collapsed surface phase, and a swollen, micelle-free core, both still part of the same network. As more surfactant is absorbed, the surface phase grows at the expense of the core, until the entire gel has collapsed. Polyacrylate (PA) gels with dodecyl- (C12TAB), and cetyltrimethylammonium bromide (C16TAB), as well as hyaluronate gels with cetylpyridinium chloride, have been studied. Kinetic experiments have been performed on macro- as well as microgels, using micromanipulator assisted light microscopy for the latter. A surfactant diffusion controlled deswelling model has been employed to describe the deswelling. The deswelling kinetics of PA microgels have been shown to be controlled by surfactant diffusion through the stagnant layer surrounding the gel, as the surface phase is relatively thin for the major part of the deswelling. For macroscopic PA gels the surface phase is thicker, and the kinetics with C12TAB were therefore also influenced by diffusion through the surface phase, while for C16TAB they were dominated by it. Relevant parameters have also been determined using equilibrium experiments. An irregular, balloon-forming deswelling pattern, mainly found for macrogels, as well as unexpectedly long lag times and slow deswelling for microgels, are reported and discussed. The microstructure of fully collapsed PA/C12TAB complexes has been studied using small-angle X-ray scattering. A cubic Pm3n structure was found at low salt concentration, which melted into a disordered micellar phase as the salt concentration was increased. Further increasing the salt concentration dissolved the micelles, resulting in no ordering.

Pharmaceutical chemistry

gel

polyelectrolyte

surfactant

deswelling

kinetics

phase separation

volume transition

ion-exchange

diffusion

liquid crystal

SAXS

cubic Pm3n

Farmaceutisk kemi

On the Structure and Dynamics of Polyelectrolyte Gel Systems and Gel-surfactant Complexes

Råsmark, Per Johan

January 2004

This thesis describes the results of experimental work on polyelectrolyte gels and their interaction with oppositely charged surfactants, and presents two new algorithms applicable to the simulation of colloid and polymer systems. The model systems investigated were crosslinked poly(acrylate) (PA) and poly(styrene sulphonate) (PSS), and the surfactant was dodecyl trimethylammonium bromide (DoTAB). Pure gel materials were studied using dynamic light scattering. It was shown that the diffusion coefficient (D) increases with increasing degree of swelling and the concentration dependence is larger than predicted by scaling arguments. For gels at swelling equilibrium D increases with increasing degree of crosslinking. In subsequent studies on gel particles in DoTAB solution, Raman spectra were recorded at different positions in the gel. For both types of gels two distinct regions could be observed. For PA the surfactant is localised in the outer phase without any surfactant in the core, while for PSS the surfactant was distributed such that it had the same concentration relative to the polymer throughout the gel. In a second experiment, the kinetics for the deswelling of microscopic PSS particles in DoTAB solution was studied. It was found that the final volume varied linearly with the DoTAB concentration, and the rate of volume decrease could be fitted to a single exponential indicating stagnant layer diffusion to be the rate limiting process for the deswelling of the PSS particles. In the second part, I first describe an algorithm showing an efficient way to detect percolation in simulations, with periodic boundary conditions, using recursion. Spherical boundary conditions is an alternative to periodic boundary conditions for systems with long-range interactions. In the last part, the possibility to use the surface of a hypersphere in four dimensions for simulations of polymer systems is investigated, and algorithms for Monte Carlo and Brownian dynamics simulations are described.

Physical chemistry

polyelectrolyte gel

microgel

dynamic light scattering

Raman spectroscopy

periodic boundary conditions

percolation

hypersphere

Monte Carlo

Brownian dynamics

Fysikalisk kemi

Physical chemistry

Fysikalisk kemi

Optimierung der Fluoreszenzgraduierung von Polyelektrolyt-Multischichten auf kolloidalen Trägern für die Durchflusszytometrie

Rosche, Christopher

24 September 2012

Die Arbeit untersucht den Einfluss des pH - Wertes auf die Fluoreszenzintensität von Multischichtsystemen während des Beschichtungsvorgangs von Siliziumdioxidpartikeln mit kovalent an Polyallylaminhydrochlorid (PAH) gebundenem Rhodamin - B - Isothiocyanat. Durch eine konsequente Pufferung mit 2 -(N - Morpholino)ethansulfonsäure während der Beschichtung kann eine Verbesserung der Homogenität der Schichtbildung und eine Erhöhung der Fluoreszenzintensität erreicht werden. Außerdem liegt eine lineare Steigerung der Fluoreszenzintensität proportional zur Anzahl der fluoreszenten Schichten vor. Weiterhin sollen kolloidale Partikel unter konstanter Pufferung zusätzlich zu Rhodamin – B – Isothiocyanat mit an PAH – gebundenem Fluoresceinisothiocyanat beschichtet werden. Dieses Farbstoffpaar weist bei Annäherung eine Fluoreszenzsteigerung durch einen Fluoreszenzresonanzenergietransfer aus. Durch Variation von Schichtanzahl und Abstand wurden verschiedene Partikelpopulationen hergestellt, die sich in Ihrer Fluoreszenzintensität analog zu einem Bead Array Assay im Durchflusszytometer klar differenzieren lassen und dabei auch eine gleichmäßige Steigerung der Fluoreszenzintensität analog zur Anzahl der fluoreszenten Schichten aufweisen.

Polyelektrolyte

Multischichten

PAH

PSS

RITC

FITC

Rhodamin - B - Isothiocyanat

Fluoreszeinisothiocyanat

Layer - by - Layer

Kolloide

polyelectrolyte

multilayer

PAH

PSS

RITC

FITC

layer - by - layer

colloids

ddc:610

Generation and Characterisation of Nanostructures from Single Adsorbed Polyelectrolyte Molecules / Herstellung und Charakterisierung von Nanostrukturen aus einzelnen adsorbierten Polyelektrolyt-Molekülen

Gorodyska, Ganna

20 September 2005

Visualization and study of reconformation of polyelectrolytes (PEs) of different architecture is of great fundamental and practical interest. Verification of theoretical predictions with experiment is of essential importance. On the other hand, a wide range of bottom-up techniques based on patterning of matter on the length scale of a few nanometers have been recently developed. Particularly interesting is the possibility of using self-assembled single molecule structures as templates for the deposition of inorganic matter, in particular metals. Synthetic &amp;quot;normal-sized&amp;quot; polymers of various architecture, like poly-2-vinylpyridine (P2VP) or polystyrene-poly(2-vynil pyridine) P2VP7-PS7 star-like block copolymer, adsorbed on solid substrates have been visualized for the first time with molecular resolution by AFM in different conformation. This finding allowed us to study largely discussed problem, a coil-to-globule transition of PEs. It was found that PE molecules undergo conformational transitions from stretched worm-like coil to compact globule via set of necklace-like globules, as the fraction of charged monomers decreases with an increase of pH and ionic strength. These results are in good agreement with recently developed DRO theory for weakly charged flexible PEs in poor solvent. The size of the deposited single molecules correlates very well with molecular dimensions in solution obtained in light scattering experiments. PE single molecules of various architectures was mineralized in different conformations that constitutes the route to nanoparticles with desired shape (including wire-shape and star-shaped), size, and composition (including metallic, magnetic and semiconductive nanoparticles). It was shown that molecular details of the adsorbed linear flexible PE molecules determine the dimensions of the nanostructures after metallization and that observed sizes are consistent with the decoration of single molecules with nanoclusters. Thus those metallized nanoparticles (cluster assembles) reflect the conformation of original adsorbed PE molecules. The dimensions of the obtained nanowires are significantly smaller than those previously reported. All of these features are of the potential benefit in applications for nanodevices. Metallization of the PS7-P2VP7 improves AFM resolution due to the selective deposition of Pd clusters along the P2VP chains. For the first time, the number of the P2VP second generation arms of the heteroarm block-copolymer was directly counted in the single molecule AFM experiment. Simple contrasting procedure was developed to improve AFM visualization of positively charged polymer chains deposited on the substrates of relatively high roughness. This method allows increasing the thickness of the resulting structures up to 10 nm, and, consequently, provide visualization of polymer chains on rough surfaces. This innovation is important for the development of single molecule experiments with polymer chains. The reaction of HCF-anion could be used for recognition of polycation molecules, when polycations, polyanions and neutral molecules coexist on the surface. Recently, the study was strongly restricted to atomically smooth surfaces. The contrasting procedure extends the range of substrates (Si-wafers, chemically modified or patterned Si-wafers, polished glasses, polymer films, etc) appropriate for the experiments. Thus, polymer single molecules can be considered not only as representative of the ensemble molecules, but also as individual nanoscale objects which can be used for future nanotechnology for the fabrication of single molecule electronic devices. Also these findings are important from fundamental point of view, since developed approach can be successfully applied for investigation of various &amp;quot;classical&amp;quot; problems in polymer science, such as polymer reconformation, interpolyelectrolyte complex formation, polymer diffusion, adsorption, etc.

Metallisierung

Polyelektrolyte

Rasterkraftmikroskopie

Visualisierung

einzelne Moleküle

atomic force microscopy

mineralization

polyelectrolyte

single molecule

visualization

ddc:540

rvk:VE 6357

Metallisieren

Molekül

Nanostruktur

Polyelektrolyt

Rasterkraftmikroskopie

Visualisierung

New Techniques for Continuous Chemical Analysis in the Pulp&Paper Industry

Rice, Matthew

January 2001

<p>This thesis presents some new techniques that were developedfor continuous chemical analysis of a paper furnish. First, ageneral background is presented, covering topics from theorigins of papermaking to present day. A short introduction topapermaking chemistry and a variety of presently availableon-line chemical analysers and measurement strategies are alsodiscussed.</p><p>A method is described for the continuous fractionation of apaper furnish containing coarse fibres (>10µm) in orderto obtain a sample for analytical purposes (Paper I). Aconsistent sample, containing a representative fraction of thedissolved and colloidal substances (DCS) present in the bulkfurnish, was achieved by preventing cake formation on a filtersurface. A combination of turbulent flow above a membranefilter, while continuously withdrawing a relatively low samplevolume, were key factors in the prevention of filterfouling.</p><p>For the continuous flow-extraction of DCS, a technique isdescribed whereby the extracting solvent was injected at a highvelocity into a continuous flow of analyte (Paper II).Comparison with conventional flow extraction showed anextraction enhancement of up to 9 times for colloidaltriglycerides.</p><p>To achieve a continuous determination of chemicalsubstances, a real-time fully automated colorimetric titrationapparatus was developed (Paper III&IV). This was achievedby using a series of micro-machined mixing channels for thecontinuous flow of analyte, with a sequence of detection unitsand titrant addition points along the flowpath (Paper III). Afuzzy logiccontroller was implemented to continuously adaptfor changes in the sample concentration, providing thepossibility of titrating over two orders of magnitude in sampleconcentration with minimal loss of accuracy (Paper IV).</p><p>Also, a system is presented whereby the filtration apparatus(Paper I) is combined with the titration device (Paper III&IV) in order to continuously determine total charge (orcolloidal charge) of a paper furnish in real-time (Paper V).This was achieved by utilising a back-titration approach andselected examples are presented showing the dynamicinteractions between wood fibres and polyelectrolyte adsorptionat various conditions of pH and polyelectrolyte molecularweight.</p><p>Finally, some suggestions for a more comprehensive wet-endchemical monitoring platform are discussed and the role of thepresent work in evaluated in this context.</p><p><b>Keywords:</b>Chemical monitoring, continuous flowextraction, cross-flow filtration, dissolved and colloidalcomponents, fuzzy-logic control, on-line system, pitchanalysis, polyelectrolyte titration, process control, samplework-up, titrimetric analysis.</p>

Chemical monitoring

continuous flow extraction

cross-flow filtration

dissolved and colloidal components

fuzzy-logic control

on-line system

pitch analysis

polyelectrolyte titration

process control

sample work-up

titrimetric analysis