Crispin Amiri Naini scite author profile

A laser temperature-jump technique is used to probe the impact of sodium halides on the temperature-dependent switching kinetics and thermodynamics of poly(N-isopropylacrylamide) brushes. An analysis on the basis of a two-state model reveals van't Hoff enthalpy and entropy changes. Sodium halides increase the endothermicity and the entropic gain of the switching process below and above Tc following the Hofmeister series: NaCl > NaBr > NaI. In contrast, enthalpic and entropic changes at Tc remain virtually unaffected. This provides an unprecedented insight into the underlying switching energetics of this classic stimuli-responsive polymer. Because of its model character, these results represent an essential reference on the way to unpuzzle the molecular driving forces of the Hofmeister effect.

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Poly(N,N-dimethylaminoethyl methacrylate) Brushes: pH-Dependent Switching Kinetics of a Surface-Grafted Thermoresponsive Polyelectrolyte

Thomas

Gajda

Naini

et al. 2015

Langmuir

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The temperature-dependent switching behavior of poly(N,N-dimethylaminoethyl methacrylate) brushes in alkaline, neutral, and acidic solutions is examined. A novel microscopic laser temperature-jump technique is employed in order to study characteristic thermodynamic and kinetic parameters. Static laser micromanipulation experiments allow one to determine the temperature-dependent variation of the swelling ratio. The data reveal a strong shift of the volume phase transition of the polymer brushes to higher temperatures when going from pH = 10 to pH = 4. Dynamic laser micromanipulation experiments offer a temporal resolution on a submillisecond time scale and provide a means to determine the intrinsic rate constants. Both the swelling and the deswelling rates strongly decrease in acidic solutions. Complementary experiments using in situ atomic force microscopy show an increased polymer layer thickness at these conditions. The data are discussed on the basis of pH-dependent structural changes of the polymer brushes including protonation of the amine groups and conformational rearrangements. Generally, repulsive electrostatic interactions and steric effects are assumed to hamper and slow down temperature-induced switching in acidic solutions. This imposes significant restrictions for smart polymer surfaces, sensors, and devices requiring fast response times.

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Probing the Intrinsic Switching Kinetics of Ultrathin Thermoresponsive Polymer Brushes

et al. 2011

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Untersuchungen zur intrinsischen Schaltkinetik ultradünner thermoresponsiver Polymerbürsten

et al. 2011

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Laserstimulierte Polymerbürsten: Die temperaturabhängige Schaltkinetik von oberflächengebundenen thermoresponsiven Polymerbürsten wurde durch ein stroboskopisches Mikromanipulations‐/Mikrocharakterisierungsverfahren zur Echtzeitmessung untersucht (siehe Bild). Intrinsische Schaltzeiten liegen im Mikro‐ und Millisekundenbereich; diese Ergebnisse könnten zur Herstellung nanodimensionierter Aktuatoren und Sensoren mit bisher unerreichtem Ansprechverhalten führen.

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Rücktitelbild: Untersuchungen zur intrinsischen Schaltkinetik ultradünner thermoresponsiver Polymerbürsten (Angew. Chem. 19/2011)

et al. 2011

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Stimuliresponsive Polymerbürsten sind bekannt für ihre einzigartigen Schalteigenschaften. In ihrer Zuschrift auf beschreiben N. Hartmann et al. eine rein optische stroboskopische Methode, die zu neuen Einblicken in die temperaturabhängige intrinsische Schaltkinetik solch ultradünner Polymerbeschichtungen führt. Im Gegensatz zu bisherigen Herangehensweisen liegen bei dieser Methode die Ansprechzeiten im Mikro‐ bis Millisekundenbereich.

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