Litcius/Paper detail

Microscale mobile surface double layer in a glassy polymer

Hailin Yuan, Jinsong Yan, Ping Gao, Sanat K. Kumar, Ophelia K. C. Tsui

2022Science Advances32 citationsDOIOpen Access PDF

Abstract

This study examines the origin of the widely different length scales, h t —nanometers to micrometers—that have been observed for the propagation of the near-surface enhanced mobility in glassy polymers. Mechanical relaxations of polystyrene films with thicknesses, h , from 5 nm to 186 μm have been studied. For h < ~1 μm, the films relaxed faster than the bulk and the relaxation time decreased with decreasing h below ~100 nm, consistent with the enhanced dynamics originating from a near-surface nanolayer. For h > ~1 μm, a bulk-like relaxation mode emerged, while the fast mode changed to one that extended over ~1 μm from the free surface. These findings evidence that the mobile surface region is inhomogeneous, comprising a nanoscale outer layer and a slower microscale sublayer that relax by different mechanisms. Consequently, measurements probing the enhanced mobility of different mechanisms may find vastly different h t ’s as shown by the literature.

Topics & Concepts

Microscale chemistryMaterials sciencePolystyreneNanoscopic scaleNanometreRelaxation (psychology)PolymerChemical physicsLayer (electronics)Surface layerNanotechnologySurface (topology)Composite materialChemistryMathematics educationSocial psychologyPsychologyGeometryMathematicsMaterial Dynamics and PropertiesAdhesion, Friction, and Surface InteractionsTheoretical and Computational Physics