The synthesis of thermoresponsive graft copolymers based on a carboxymethylcellulose
(CMC) backbone is reported. Thermal responsive properties are introduced by grafting the CMC sample
with amino-terminated poly(N-isopropylacrylamide) (PNIPAM) side chains of a relatively low molecular
weight. Turbidity measurements in dilute copolymer solutions showed that, due to the hydrophilic CMC
backbone, macroscopic phase separation by increasing temperature above the lower critical solution
temperature (LCST) of PNIPAM is not allowed for pH ≥ 3. Pyrene fluorescence probing studies in aqueous
solutions revealed the formation of hydrophobic microdomains above the LCST of PNIPAM. In semidilute
solution these microdomains interconnect the polymer chains, leading to the thermally induced formation
of a physical network. The macroscopic result is the observation in semidilute solutions of a pronounced
thermally induced viscosity enhancement. This thermothickening phenomenon is almost irrespective of
pH, and it remains very important even at pH values as low as 3.
Summary: A technique to cover microelectromechanical systems (MEMS), such as micromechanical cantilever (MC) sensors, with a covalently bound brush layer has been developed. The polymer layer was grown using a “grafting‐from” synthesis of polymer brushes under mild conditions, by surface‐initiated atom transfer radical polymerization. Atomic force microscopy (AFM) and ellipsometry have revealed a uniform thickness of about 12 nm from which a grafting density of polymer brushes of 0.19 chains · nm−2 was estimated. The coating with polymer brushes can be realized on a selected surface. It was shown that a single‐sided brush layer swells reversibly in toluene, resulting in a bending of the micromechanical cantilever.Schematic representation of the PMMA brush synthesis on the MC surface, by surface‐initiated ATRP.magnified imageSchematic representation of the PMMA brush synthesis on the MC surface, by surface‐initiated ATRP.
Polymer brush coatings are well-known for their ability to tailor surface properties in a wide range of applications from colloid stabilization to medicine. In most cases, the brushes are used in solution. Consequently, efforts were expended to experimentally investigate or theoretically predict the swelling behavior of the brushes in solvents of different qualities. Here, we show that the micromechanical cantilever (MC) sensor technique is a tool to perform time-resolved physicochemical investigations of thin layers such as polymer brushes. Complementary to scattering techniques, which measure the thickness, the MC sensor technique provides information about changes in the internal pressure of the brushes during a swelling and deswelling process. We show that the kinetics of both swelling and deswelling are dependent on solvent quality. Comparing the measured data with its thickness evolution, which was calculated based on the Flory-Huggins theory, we found that only the first 10% of the thickness increase of the polymer brush results in a significant pressure increase inside the polymer brush layer.
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