Confined crystallization, crystalline phase deformation and their effects on the properties of crystalline polymers

Wang, Haopeng

January 2009

No description available.

Chemical Engineering

Materials Science

Plastics

Polymers

Confined crystallization

nanolayer

coextrusion

gas permeability

olefin block copolymer

free volume

DYNAMICS OF POLYMER SELF-ASSEMBLY BY COMPUTER SIMULATION

LI, ZHENLONG

21 March 2011

No description available.

Polymers

self-assembly dynamics

block copolymer micelles

supramolecular polymer

computer simulation

DPD simulation

Molecular Dynamics simulation

micelle dynamics

viscosity

Synthesis and Characterization of Poly(2-Ethyl-2-Oxazoline) Functional  Prepolymers and Block Copolymers

Celebi, Oguzhan

19 January 2014

This dissertation focuses on the synthesis and characterization of functional poly(2-ethyl-2-oxazoline) (PEtOx) containing homo- and block copolymers that are potential materials for membrane-based water purification and gas separation, drug delivery, magnetic resonance imaging and tissue engineering applications. The polymerization of 2-ethyl-2-oxazoline (EtOx) was investigated with regard to the effects of initiator structures and reaction parameters such as polymerization time and temperature on molecular weight control and molecular weight distribution, endgroup functionality, living characteristics, and mechanism and kinetics. The structure of initiators was shown to significantly affect the molecular weight control and molecular weight distribution of PEtOx oligomers. Methyl triflate initiated polymerizations were found to result in oligomers with low polydispersity (PDI) values around 1.10-1.15 and symmetrical chromatograms were obtained via size exclusion chromatography (SEC) studies with the use of refractive index, light scattering and viscosity detectors. However, EtOx polymerizations initiated by halide containing initiators such as benzyl chloride, dibromo- and diiodo-p-xylene, and vinylsilylpropyl iodides yielded PEtOx oligomers with higher PDI values ~ 1.30-1.40. Higher molecular weight distributions can be attributed to the presence of covalent species during polymerization and slower initiation rate as evidenced by kinetic studies when compared to PEtOx prepared from methyl triflate initiators. In all cases, termination reactions with aliphatic cyclic amines were quantitative. Mono- and diamine functional PEtOx oligomers with controlled molecular weight and excellent end-group functionality may be used as prepolymers for incorporation into multiblock and graft copolymer and crosslinked structures for a variety of applications such as membranes and hydrogels for tissue engineering matrices. Poly(2-ethyl-2-oxazoline) containing block copolymers were prepared using the macroinitiator method. First, amphiphilic triblock copolymers with hydrophobic poly(arylene ether sulfone) (PSF) central block and hydrophilic PEtOx side blocks were synthesized via polymerization of EtOx sequences from tosylate functional telechelic PSF macroinitiators. PSFs are well-known engineering thermoplastics with excellent resistance to hydrolysis and oxidation, as well as displaying good mechanical properties, thermal stability and toughness. Phenol functional PSFs were prepared via step-growth polymerization of dichlorodiphenylsulfone and bisphenol-A (slight excess) monomers. Phenolic chain ends were then converted to aliphatic hydroxyethyl endgroups by reaction with ethylene carbonate. Upon treatment with p-toluenesulfonyl chloride, tosylate functional PSF macroinitiators were prepared. PEtOx-b-PSF-b-PEtOx triblock copolymers (pendent acyl groups of PEtOx side blocks) were partially hydrolyzed in an acidic medium to introduce random charged poly(ethylene imine) units to prepare ionomer structures that may show good salt rejection, water flux and antibacterial properties for membrane-based water purification applications. Phosphonic acid modified poly(ethylene oxide)-b-poly(2-ethyl-2-oxazoline) (PEO-b-PEtOx) diblock copolymers were prepared via cationic ring opening polymerization of EtOx monomers from tosylate functional PEO macroinitiators and subsequent functionalization reactions on the polyoxazoline block. Post-modification reactions included controlled partial pendent acyl group hydrolysis under an acidic medium to form the random block copolymers of PEtOx and poly(ethyleneimine) (PEI), Michael addition of diethylvinyl phosphonate groups to PEI units and hydrolysis of the ethyl groups on the phosphonates to yield pendent phosphonic acid groups on the polyoxazoline block. After each step of functionalization reactions, structures and compositions were confirmed utilizing 1H NMR and the degree of phosphorylation was found to be > 95%. Both PEO and PEtOx are biocompatible polymers and the anionic quality of the phosphonic acid has the potential to be pH controllable and provide an environment where cationic drugs and contrast agents can be attached. Thus, these polymers have potential as drug carriers and contrast enhancement agents for magnetic resonance imaging applications. / Ph. D.

Oxazoline

membrane

block copolymer

2-ethyl-2-oxazoline

prepolymer

cationic ring opening polymerization

size exclusion chromatography

phosphonate

Investigation of the Influence of Selected Variables on the Solid State Structure-Property Behavior of Segmented Copolymers

Sheth, Jignesh Pramod

31 January 2005

Segmented copolymers are a commercially important class of materials that are utilized in a wide variety of applications. In these systems a relatively large number of variables such as backbone chemistry, segment molecular weight, and the overall molecular weight of the copolymer can be independently controlled to engineer materials with targeted properties. Such versatility also means that a large number of variables can influence the morphology and therefore, properties and performance of segmented copolymers. In this dissertation, the influence of selected variables on the solid state structure-property behavior of segmented poly(ether-block-amide), polyurethane, polyurethaneurea, and polyurea copolymers is explored. The specific variables which have been utilized singly or in conjunction with others are hard segment crystallizability, crystallization conditions, hard segment content, soft segment type and molecular weight, nature of hydrogen bonding, extent of inter-segmental hydrogen bonding, segment symmetry, and chain architecture. In poly(ether-block-amide)s, it was found that the morphology of both the crystalline and the amorphous phase depend upon the polyamide content of the sample and, as expected, the crystallization conditions. A comparison of polydimethylsiloxane based segmented polyurethanes with their polyurea counterparts demonstrated that for a constant hard segment content the soft segment molecular weight particularly governs the extent of microphase separation in these materials. The nature of hydrogen bonding, monodentate or bidentate, also strongly influences their mechanical response. Remarkably, the polyurea sample with a polydimethylsiloxane molecular weight of 7000 g/mol and a hard segment content of 25 wt % exhibited a remarkable service temperature window (for rubber-like behavior) of ca. 230°C (from -55°C to 175°C) whereas it was ca. 200°C wide (from -55°C to 145°C) for the equivalent polyurethane sample. The extremely high chemical incompatibility between the polydimethylsiloxane of sufficiently high molecular weight and urethane or urea segment is expected to generate a relatively sharp interface between the soft matrix and the dispersed hard domains. Therefore, a polyether co-soft segment was incorporated in a controlled manner along the chain backbone, which resulted in inter-segmental hydrogen bonding between the ether and the urea segments. The consequent segmental mixing gave rise to a gradient interphase, which led to a significant improvement in the tensile strength, and elongation at break in selected polydimethylsiloxane segmented polyurea copolymers. The importance of the hydrogen bonding network in model polyurethaneurea copolymers was also explored by utilizing LiCl as molecular probe. It has been demonstrated that hydrogen bonding plays an important role, over and above microphase separation, in promoting the long-range connectivity of the hard segments and the percolation of the hard phase through the soft matrix. The incorporation of hard segment branching in these polyurethaneurea also reduced the ability of the hard segments to pack effectively and establish long-range connectivity. The disruption of the percolated hard phase resulted in a systematic softening of the copolymers. The role of chain architecture in governing the structure/property/processing of segmented was also investigated by comparing highly branched segmented polyurethaneureas with their linear analogs. These copolymers were based on poly(propylene oxide) or poly(tetramethylene oxide) as the soft segments The highly branched copolymers utilized in this dissertation were able to develop a microphase morphology similar to their linear analogs. Particularly noteworthy, and surprising, was the observation of weak second order interference shoulder in the respective small angle X-ray scattering profiles of the highly branched samples based on poly(propylene oxide) of MW 8200 and 12200, indicating the presence of at least some level of long-range order of the hard domains in these samples. Tapping-mode atomic force microscopy phase images of these two samples clearly confirmed the small angle X-ray scattering results. In addition to the strain induced crystallization of the poly(tetramethylene oxide) MW 2000 g/mol based linear polyurethaneureas, the highly branched analog of this sample also exhibited similar behavior at ambient temperature and uniaxial deformation of ca. 400 % strain. Wide angle X-ray scattering confirmed the above observation. The reduced ability of the branched polymers to entangle resulted in slightly poorer mechanical properties, such as tensile strength, elongation at break, and stress relaxation as compared to their linear analogs. However, primarily due to their reduced entanglement density, the branched polyurethaneureas had significantly lower ambient temperature solution viscosity as compared to their linear polyurethaneurea analogs. Therefore, these highly branched polyurethaneureas can be more easily processed than the latter materials. Finally, it was demonstrated that non-chain extended segmented polyurethane and polyurea copolymers in which the hard segment is based on only a single diisocyanate molecule may well exhibit properties, such as the breadth of the service window, the average plateau modulus, stiffness, tensile strength, and elongation at break that are similar to chain extended segmented copolymers that possess distinctly higher hard segment content. A careful control of the hard segment symmetry and the nature of the hydrogen bonding is necessary to achieve such improved performance in the non-chain extended systems. Therefore, the results of this study provide new direction for the production of thermoplastic segmented copolymers with useful structural properties. / Ph. D.

structure-property behavior

hydrogen bonding

polyurethane

poly(ether-block-amide)

microphase separation

segmented copolymer

atomic force microscopy

Polímeros bioestables para fabricación de implantes protésicos: caracterización físico-química y respuesta biológica in vitro

Campillo Fernández, Alberto José

17 November 2014

La necesidad de polímeros bioestables para fabricación de implantes protésicos queda patente, entre otros indicadores, por la proliferación de dispositivos actualmente comercializados. La caracterización físico-química así como la respuesta biológica de un conjunto de materiales poliméricos bioestables es el objetivo último de esta tesis. En este trabajo se han sintetizado diferentes materiales poliméricos de la familia de los acrilatos y metacrilatos variando sutilmente sus características superficiales, como el grado de hidrofilia o la distribución de cargas eléctricas. El procedimiento consistió en la copolimerización via radical de acrilato de etilo, EA, acrilato de 2-hidroxietilo, HEA, y ácido metacrílico, MAAc. Se ha caracterizado los materiales en estado seco y en presencia de diferentes contenidos de agua mediante calorimetría diferencial de barrido, DSC, análisis dinámico-mecánico, DMA, microscopía de fuerza atómica, AFM, análisis dieléctrico, DRS, contenido de agua en equilibrio, EWC, y energía superficial, SE, persiguiendo el objetivo de dilucidar si el agua es capaz de inducir cambios conformacionales en las cadenas poliméricas que den lugar a una separación de fases. Sobre los materiales en forma de scaffold poroso con poros esféricos interconectados se ha cultivado fibroblastos y endoteliales. La compatibilidad de las células endoteliales se midió en términos de viabilidad celular y la adecuada diferenciación endotelial y su funcionamiento. Se han realizado cultivos de células endoteliales humanas primarias, HUVEC, y se ha determinado si su morfología y función se vio afectada por el material. Se examinó la adhesión y proliferación de las mismas, así como un marcador importante de activación endotelial, la E-selectina. Se evaluó si se mantuvieron los fenotipos endoteliales normales y sus funciones observadas in vivo mediante análisis de los contactos célula-célula y la regulación de la expresión génica del marcador de activación E-selectina cuando se añadió un estímulo (LPS). Además, como posible aplicación de estos materiales en una prótesis de córnea artificial, y dado que los fibroblastos del estroma de la córnea (es decir, los queratocitos) son de relevancia en la cicatrización de la córnea se determinó cómo afectaba la hidrofilicidad del substrato a la adhesión celular de la línea de fibroblastos humanos MRC-5, como modelo celular para estudiar la disposición del citoesqueleto tras la adhesión a los diferentes soportes mediante la detección de F-actina. Asimismo, se ha sembrado células epiteliales evaluando su comportamiento/funcionamiento celular ya que uno de los requisitos esenciales para que un implante de queratoprótesis tenga éxito es que se cree y mantenga una capa de células epiteliales que impidan entrar a las bacterias al interior del ojo y permita la difusión la capa lagrimal de manera estable en el tiempo. Así, se han analizado parámetros celulares como adhesión, proliferación y viabilidad de una línea de células epiteliales de conjuntiva humana, NHC, cultivada sobre substratos poliméricos con diferentes grados de hidrofilia y cargas eléctricas superficiales buscando qué grado de hidrofilicidad permite la epitelización del substrato y podría darle al material flexibilidad y la hidrofilicidad necesaria para un mejor contacto con los párpados y lágrima. Los resultados obtenidos se han correlacionado con la adsorción y conformación de una proteína de la matriz extracelular, la fibronectina. / Campillo Fernández, AJ. (2014). Polímeros bioestables para fabricación de implantes protésicos: caracterización físico-química y respuesta biológica in vitro [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/44232 / Premios Extraordinarios de tesis doctorales

Acrylates

Methacrylates

Hydrogel

Scaffold

Copolymer networks

Nanoheterogenity

Hydrophobic effect

Fibroblasts

Epithelial cells

HUVEC

Fibronecti

MAQUINAS Y MOTORES TERMICOS

FISICA APLICADA

Morphological Characterization and Analysis of Ion-Containing Polymers Using Small Angle X-ray Scattering

Zhang, Mingqiang

03 February 2015

Small angle X-ray scattering (SAXS) has been widely used in polymer science to study the nano-scale morphology of various polymers. The data obtained from SAXS give information about sizes and shapes of macromolecules, characteristic distances of partially ordered materials, pore sizes, and so on. The understanding of these structural parameters is crucial in polymer science in that it will help to explain the origin of various properties of polymers, and guide design of future polymers with desired properties. We have been able to further develop the contrast variation method in SAXS to study the morphology of Nafion 117CS containing different alkali metal ions in solid state. Contrast variation allows one to manipulate scattering data to obtain desired morphological information. At room temperature, only the crystalline peak was found for Na⁺-form Nafion, while for Cs⁺-form Nafion only the ionic peak was observed. The utilization of one dimensional correlation function on different counterion forms of Nafion further demonstrates the necessity of contrast variation method in obtaining more detailed morphological information of Nafion. This separation of the ionic peak and the crystalline peak in Nafion provides a means to independently study the crystalline and ionic components without each other's effect, which could be further applied to other ionomer systems. We also designed time resolved SAXS experiments to study the morphological development during solution processing Nafion. As solvent was removed from Nafion dispersion through evaporation, solid-state morphological development occurred through a variety of processes including phase-inversion, aggregation of interacting species (e.g., ionic functionalities), and crystallization of backbone segments. To probe the real-time morphological development during membrane processing that accurately simulates industrial protocols, a unique sample cell has been constructed that allows for through-film synchrotron SAXS data acquisition during solvent evaporation and film formation. For the first time, this novel experiment allows for a complete analysis of structural evolution from solution/dispersion to solid-state film formation, and we were able to show that the crystallites within Nafion develop later than the formation of ionic domains, and they do not reside in the cylindrical particles, but are dispersed in solution/dispersion. Besides bulk morphology of Nafion, we have also performed Grazing Incident SAXS to study the surface morphology of Nafion. We were able to manipulate the surface morphology of Nafion via neutralizing H⁺-form Nafion with different large organic counterions, as well as annealing Nafion thin films under different temperatures. This not only allows to obtain more detailed information of the nano-structures in Nafion thin films, but also provides a means to achieve desired morphology for better fuel cell applications. We have also been able to study the polymer chain conformation in solution via measuring persistence length by utilizing solution SAXS. Different methods have been applied to study the SAXS profiles, and the measured persistence lengths for stilbene and styrenic alternating copolymers range from 2 to 6 nm, which characterizes these copolymers into a class of semi-rigid polymers. This study allows to elucidate the steric crowding effect on the chain stiffness of these polymers, which provides fundamental understanding of polymer chain behaviors in solution. Self-assembling in block copolymers has also been studied using SAXS. We established a morphological model for a multiblock copolymer used as a fuel cell material from General Motors®, and this morphological model could be used to explain the origins of the mechanical and transport properties of this material. Furthermore, several other block copolymers have been studied using SAXS, which showed interesting phase separated morphologies. These morphological data have been successfully applied to explain the origins of various properties of these block copolymers, which provide fundamental knowledge of structure-property relationship in block copolymers. / Ph. D.

solution processing

small angle X-ray scattering

morphology

block copolymer

proton exchange membrane

ionomer

Nafion®

perfluorosulfonic aid ionomer

Probing diffusion and molecular dynamics to study self-assembly and intermolecular interactions in macromolecular and colloidal systems using NMR diffusometry and spectroscopy

Uppala, Veera Venkata Shravan

13 January 2025

The growing demand for technological advancements in energy storage and pharmaceuticals, driven by population growth and climate change, has created an urgent need for the development of novel materials with finely tuned and targeted properties. Polymers, with their inherent versatility, have emerged as key players in modulating the functionality of such advanced materials. However, achieving precise control over the performance of the materials requires a deep understanding of the molecular interactions, self-assembly processes, and transport phenomena that govern their behavior at the nanoscale. This dissertation focuses on the application of advanced nuclear magnetic resonance (NMR) techniques to probe the molecular dynamics and diffusion behavior in complex macromolecular and colloidal systems. Two key NMR techniques – NMR diffusometry and dynamic NMR spectroscopy – are employed to probe the motion and exchange process of molecules within these systems. By providing insights into the dynamics of the constituents, these methods are particularly powerful in unraveling the intermolecular interactions that govern material functionality. The materials under investigation include block copolymer micelles (BCMs), ligand-capped quantum dots (QDs), and linear polyelectrolyte chains – each with unique structural characteristics and promising applications. Block copolymer micelles are of particular interest for drug delivery applications due to their ability to encapsulate and release therapeutic agents in controlled manner. Colloidal quantum dots, with their size-tunable electronic properties, have great potential in photovoltaics and biosensing. Linear polyelectrolytes, characterized by their charged backbones, are crucial for energy storage and biomedical applications. Through a detailed analysis of the translational motion of molecules, this work reveals key molecular insights, including intermolecular interactions, the coexistence of molecules in distinct chemical environments, and their exchange mechanism between these environments. These findings establish critical structure-property relationships in each material system, providing a foundation for rational design and optimization of their functional performance. The results obtained in this research not only contribute to our fundamental understanding of the molecular behavior of these complex systems but also have practical implications for design of next-generation materials. By leveraging the power of NMR-based techniques, this dissertation offers a pathway for enhancing material properties in the desired applications. The findings emphasize the critical role of molecular characterization techniques in advancing the field of material science and facilitating the development of more efficient, high-performance materials tailored to meet the demands for modern technology. / Doctor of Philosophy / Rising global challenges, such as energy storage and healthcare, demand innovations for new technologies. At the core of many of these innovations are advanced materials, which must be meticulously designed to meet specific performance requirements. Polymers, in particular, play a key role in these developments due to their versatile properties. To create materials with precise functionality, a deeper understanding of the chemistry and molecular interactions that govern their behavior is essential. This dissertation focuses on using nuclear magnetic resonance (NMR), a powerful analytical tool, to probe molecular motions and interactions in advanced materials. Specifically, this research has developed NMR methodologies to investigate polymer-based micelles (surfactants) for drug-delivery applications, semiconductor nanoparticles for solar cells and sensor applications, and molecular weight determination of charged polymer chains. The research aims to reveal new insights into the behavior of these materials and how such knowledge can be harnessed to design more effective systems for applications in medicine and energy. By studying molecular motions and interactions, this work aspires to contribute to the development of next-generation materials capable of addressing some of the world's most pressing challenges.

Energy storage

pharmaceuticals

polymers

self-assembly

transport

NMR diffusometry

NMR spectroscopy

block copolymer micelles

quantum dots

polyelectrolytes

structure-property relationships

Synthesis and characterisation of block copolymers and cyclic polymers containing poly(p-phenylenevinylene)s

Lidster, Benjamin John

January 2015

Conjugated organic polymers have attracted immense interest for use in the active layer of photovoltaic cells, electroluminescent displays and diagnostic sensors. Precise control of the chemical structure of these conjugated materials is essential to achieve better device performance and certain structural aspects which have received minimal investigation include; the nature of the end groups, the precise control of the molecular weight and the formation of novel polymer topologies. Absolute control of these factors, in particular the end groups, has the potential to further tune the electro-optical properties, eliminate charge trapping and reactive sites, and facilitate block copolymer formation. The ring opening metathesis polymerisation of highly strained cyclophanediene monomers has proven to be an advantageous route to obtain soluble poly(p-phenylenevinylene)s (PPVs). In an extension of this previous work PPVs with both a pristine polymer backbone microstructure and a range of well-defined functional end groups have been prepared. These polymers exhibited excellent degrees of functionality, relatively narrow unimodal distributions and degrees of polymerisation much higher than those attainable by alternate routes. In particular the incorporation of an α-bromoester end group directly resulted in PPVs which were effective macroinitiators in the atom transfer radical polymerisation of methyl methacrylate. The diblock copolymers prepared by this route were isolated with narrow polydispersities, unimodal distributions and were free from homopolymer impurities. This method of preparing rod-b-coil diblock copolymers, where the properties of the two segments can readily be modified, provides access to materials which are of interest for both their self-assembly ability and for the development of a much required phase diagram in this area. Cyclic PPVs are of synthetic interest both for the absence of any end groups and for an infinitely long π-conjugated backbone, both of which are expected to contribute to unique electro-optical properties. The preparation of these target polymers was investigated by the ring expansion metathesis polymerisation of the cyclophanediene monomers. The formation of purely cyclic, low molecular weight PPVs was found to be highly dependent on both the reaction conditions used and the nature of the solubilising substituents. For example the preparation of purely cyclic PPVs with alkoxy side chains was unsuccessful, however the incorporation of alkyl side chains allowed for the successful isolation of the desired cyclic polymers.

668.9

The correlation of the molecular structure of polyolefins with environmental stress cracking resistance

Shebani, Anour Nasser

12 1900

Thesis (MSc (Chemistry and Polymer Science))--University of Stellenbosch, 2006. / This study concerns the phenomenon of environmental stress cracking resistance (ESCR) in three impact polypropylene copolymers (IPPCs). The main purpose was to correlate the ESCR with their properties such as microstructure, molecular weight (MW), molecular weight distribution (MWD), crystallinity and morphology. Initially the selection of a suitable test method and an active stress cracking agent (SCA) were the preliminary concerns. The Bell telephone test was used to evaluate SCAs, while a published procedure for determining ESCR of ethylene based plastics was adapted for the purpose of this study. Isopropanol was selected as SCA. Polymers were fully characterized by FTIR, 13C NMR, DSC and high temperature GPC. Optical microscopy was used to investigate craze formation and crack growth, and scanning electron microscopy (SEM) was used to study the morphology of the polymers. Since IPPCs are known to have multi-fraction copolymeric structures and each of these fractions has significantly different average properties, fractions were selectively removed from the materials, either by solvent extraction at room temperature, or by TREF fractionation. The effect of removing these fractions on the ESCR was determined. The effect of the molecular composition of the three IPPCs on the ESCR of these materials, as well as the effect of the removal of the selected molecular fractions on the ESCR, morphology and molecular characteristics are discussed and compared. Conclusions are drawn as to the factors controlling ESCR in these materials.

Environmental stress cracking (ESR)

Impact polypropylene copolymer

Dissertations -- Polymer science

Theses -- Polymer science

Chemistry and Polymer Science

Polymers in Aqueous Lubrication

An, Junxue

January 2017

The main objective of this thesis work was to gain understanding of the layer properties and polymer structures that were able to aid lubrication in aqueous media. To this end, three types of polyelectrolytes: a diblock copolymer, a train-of-brushes and two brush-with-anchor mucins have been utilized. Their lubrication ability in the boundary lubrication regime has been examined by Atomic Force Microscopy with colloidal probe. The interfacial behavior of the thermoresponsive diblock copolymer, PIPOZ60-b-PAMPTAM17,on silica was studied in the temperature interval 25-50 ˚C. The main finding is that adsorption hysteresis, due to the presence of trapped states, is important when the adsorbed layers are in contact with a dilute polymer solution. The importance of trapped states was also demonstrated in the measured friction forces, where significantly lower friction forces, at a given temperature, were encountered on cooling than on the preceding heating stage, which was attributed to increased adsorbed amount. On the heating stage the friction force decreased with increasing temperature despite the worsening of the solvent condition, and the opposite trend was observed when using pre-adsorbed layers (constant adsorbed amount) as a consequence of increased segment-segment attraction. The second part of the studies was devoted to the interfacial properties of mucins on PMMA. The strong affinity provided by the anchoring group of C-PSLex and C-P55 together with their more extended layer structure contribute to the superior lubrication of PMMA compared to BSM up to pressures of 8-9 MPa. This is a result of minor bridging and lateral motion of molecules along the surface during shearing. We further studied the influence of glycosylation on interfacial properties of mucin by utilizing the highly purified mucins, C-P55 and C-PSLex. Our data suggest that the longer and more branched carbohydrate side chains on C-PSLex provide lower interpenetration and better hydration lubrication at low loads compared to the shorter carbohydrate chains on C-P55. However, the longer carbohydrates appear to counteract disentanglement less efficiently, giving rise to a higher friction force at high loads. / <p>QC 20170407</p>

Lubrication

boundary lubrication

friction

surface forces

adsorption

adsorption hysteresis

non-equilibrium state

diblock copolymer

polyelectrolyte

thermoresponsive

mucin

QCM-D

ellipsometry

AFM

Physical Chemistry

Fysikalisk kemi