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Charakterisierung Plasmamodifizierter Elastomer-OberflächenMeyer, Thorsten 09 January 2006 (has links)
Heute werden Polymere für zahlreiche Anwendungen eingesetzt. Oftmals ist das Verkleben, Bedrucken, Beschichten oder Benetzen von Polymeren aber problematisch, da sie eine niedrige Oberflächenenergie aufweisen. Eine Plasmabehandlung der Polymeroberfläche kann die Oberflächenenergie stark erhöhen und die genannten Verarbeitungsverfahren ermöglichen. Bei einer solchen Plasmabehandlung reagieren die Ionen und Radikale des Plasmas mit der Polymeroberfläche und erzeugen dort funktionale Gruppen, welche die Oberflächeneigenschaften des Polymers bestimmen.In dieser Arbeit sollen die Oberflächeneigenschaften ausgewählter Polymere mittels Plasmabehandlung dahingehend modifiziert werden, dass ihre Oberflächenenergien von sehr hoch" nach sehr gering" schaltbar sind. So kann eine Oberfläche zunächst von Wasser stark benetzend sein, also hydrophil und dann durch kurze Plasmabehandlung total unbenetzend, also hydrophob sein. Diese Plasmaaktivierungen sollen möglichst schnell, mechanisch stabil und reversibel sein.Um die Reaktionen im Plasma besser auflösen zu können, wird das komplexe HNBR (Hydriertes Nitril Butadien Gummi) zunächst in einfache Modellsysteme wie Polyethylen, Polybutadien und Polyacrylnitril zerlegt.
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Fabrication and Study of Switchable Polymer Layers with Hydrophobic/Hydrophilic Behavior / Herstellung und Untersuchung schaltbarer Polymerschichten mit hydrophobem/ hydrophilem CharakterMotornov, Mikhail 07 November 2004 (has links) (PDF)
The framework of this thesis aims to fabricate materials, which change surface characteristics in response to environmental conditions. This response may be employed to improve material characteristics as adhesion, wettability, interaction with cells etc. The mixed brushes introduce adaptive and switching behavior in different surrounding media. Two main approaches were employed to fabricate mixed polymer brushes: "grafting to" and "grafting from". Mixed PS/PVP polymer brushes were synthesized via step-by-step grafting of these two polymers from polyamide (PA) surfaces. NH3 plasma was used for the introduction of amino and OH functionalities on PA surfaces with following attachment of azo initiator of radical polymerizaton. The mixed brushes prepared on the surface of PA textiles combine both the switching effect and effect of composite surface (i.e. micrometer scale roughness) which substantially amplifies the switching range. Mixed polymer brushes prepared from P(S-b-2VP-b-EO) and P(S-b-4VP) block copolymers were grafted to both the flat surface of Si wafers and to the surface of silica nanoparticles via quaternization reaction of the pyridine nitrogen. This one step grafting technique has a substantial advantage over the multistep grafting of mixed polymer brushes. We have demonstrated that combination of the two level hierarchical organization of polymer films at macroscopic and nanoscopic levels resulted in the formation of self adaptive surfaces switchable in controlled environment from ultra-hydrophobic to hydrophilic energetic states. The PFS/PVP mixed brush was grafted onto the pre-treated PTFE surface (plasma etching) with the needle like topography. The size of vertical needles was at micron scale. If the brush is switched to the hydrophobic state the layer has shown a unique ultra-hydrophobic behavior (complete non-wetting) with the contact angle approaching value of 160o. If the mixed brush was switched into the hydrophilic state the surface became completely wetted due to the capillary forces in the pores formed by the needle like structure. Thus, the surface can be either highly wettable or completely non-wettable with the self cleaning properties.
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Fabrication and Study of Switchable Polymer Layers with Hydrophobic/Hydrophilic BehaviorMotornov, Mikhail 24 June 2004 (has links)
The framework of this thesis aims to fabricate materials, which change surface characteristics in response to environmental conditions. This response may be employed to improve material characteristics as adhesion, wettability, interaction with cells etc. The mixed brushes introduce adaptive and switching behavior in different surrounding media. Two main approaches were employed to fabricate mixed polymer brushes: "grafting to" and "grafting from". Mixed PS/PVP polymer brushes were synthesized via step-by-step grafting of these two polymers from polyamide (PA) surfaces. NH3 plasma was used for the introduction of amino and OH functionalities on PA surfaces with following attachment of azo initiator of radical polymerizaton. The mixed brushes prepared on the surface of PA textiles combine both the switching effect and effect of composite surface (i.e. micrometer scale roughness) which substantially amplifies the switching range. Mixed polymer brushes prepared from P(S-b-2VP-b-EO) and P(S-b-4VP) block copolymers were grafted to both the flat surface of Si wafers and to the surface of silica nanoparticles via quaternization reaction of the pyridine nitrogen. This one step grafting technique has a substantial advantage over the multistep grafting of mixed polymer brushes. We have demonstrated that combination of the two level hierarchical organization of polymer films at macroscopic and nanoscopic levels resulted in the formation of self adaptive surfaces switchable in controlled environment from ultra-hydrophobic to hydrophilic energetic states. The PFS/PVP mixed brush was grafted onto the pre-treated PTFE surface (plasma etching) with the needle like topography. The size of vertical needles was at micron scale. If the brush is switched to the hydrophobic state the layer has shown a unique ultra-hydrophobic behavior (complete non-wetting) with the contact angle approaching value of 160o. If the mixed brush was switched into the hydrophilic state the surface became completely wetted due to the capillary forces in the pores formed by the needle like structure. Thus, the surface can be either highly wettable or completely non-wettable with the self cleaning properties.
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