AI Article Synopsis
- The study explores how CO2 annealing affects melting and crystallization in ultrathin films of poly(ethylene oxide) (PEO) on silicon substrates.
- The PEO films melted at a lower pressure and temperature than bulk PEO, and quick depressurization led to a non-equilibrium state before subsequent crystallization.
- Key findings include a consistent flat-on lamellar orientation of molecular chains across varying film thicknesses and slower dewetting rates for thinner films, attributed to irreversibly adsorbed layers formed during CO2 treatment which influence the crystallization and dewetting processes.
Article Abstract
The effects of CO2 annealing on the melting and subsequent melt crystallization processes of spin-cast poly(ethylene oxide) (PEO) ultrathin films (20-100 nm in thickness) prepared on Si substrates were investigated. By using in situ neutron reflectivity, we found that all the PEO thin films show melting at a pressure as low as P = 2.9 MPa and at T = 48 °C which is below the bulk melting temperature (Tm). The films were then subjected to quick depressurization to atmospheric pressure, resulting in the non-equilibrium swollen state, and the melt crystallization (and/or dewetting) process was carried out in air via subsequent annealing at given temperatures below Tm. Detailed structural characterization using grazing incidence X-ray diffraction, atomic force microscopy, and polarized optical microscopy revealed two unique aspects of the CO2-treated PEO films: (i) a flat-on lamellar orientation, where the molecular chains stand normal to the film surface, is formed within the entire film regardless of the original film thickness and the annealing temperature; and (ii) the dewetting kinetics for the 20 nm thick film is much slower than that for the thicker films. The key to these phenomena is the formation of irreversibly adsorbed layers on the substrates during the CO2 annealing: the limited plasticization effect of CO2 at the polymer-substrate interface promotes polymer adsorption rather than melting. Here we explain the mechanisms of the melt crystallization and dewetting processes where the adsorbed layers play vital roles.
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| http://dx.doi.org/10.1039/c4sm00683f | DOI Listing |
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