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Thermoresponsive Nanoparticles with Cyclic-Polymer-Grafted Shells Are More Stable than with Linear-Polymer-Grafted Shells: Effect of Polymer Topology, Molecular Weight, and Core Size

Max Willinger, Erik Reimhult

2021The Journal of Physical Chemistry B21 citationsDOIOpen Access PDF

Abstract

) on two different core sizes (3.7 and 9.2 nm) and as free polymer were investigated. We observed the critical flocculation temperature (CFT) during temperature cycling dynamic light scattering experiments, the critical solution temperature (CST), and the transition enthalpy per monomer during differential scanning calorimetry measurements. When all conditions are identical, cyclic polymers increase the colloidal stability and the critical flocculation temperature compared to their linear counterparts. Furthermore, the cyclic polymer shows only one uniform transition, while we observe multiple transitions for the linear polymer shells. We link the single transition and higher colloidal stability to the absence in cyclic PiPrOx shells of a dilute outer part where the particle shells can interdigitate.

Topics & Concepts

PolymerMaterials scienceDynamic light scatteringSmart polymerDifferential scanning calorimetryNanoparticleChemical engineeringLower critical solution temperaturePolymer chemistryGlass transitionTopology (electrical circuits)NanotechnologyThermodynamicsCopolymerComposite materialEngineeringCombinatoricsMathematicsPhysicsSurfactants and Colloidal SystemsCoagulation and Flocculation StudiesNanoparticle-Based Drug Delivery
Thermoresponsive Nanoparticles with Cyclic-Polymer-Grafted Shells Are More Stable than with Linear-Polymer-Grafted Shells: Effect of Polymer Topology, Molecular Weight, and Core Size | Litcius