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Dynamics of DiPGME-Water Mixtures in Mesoporous Silica

M. Sattig ; Khalid Elamin (Institutionen för fysik, Kondenserade materiens fysik (Chalmers)) ; M. Reuhl ; Jan Swenson (Institutionen för fysik, Kondenserade materiens fysik (Chalmers)) ; M. Vogel
Journal of Physical Chemistry C (1932-7447). Vol. 121 (2017), 12, p. 6796-6806.
[Artikel, refereegranskad vetenskaplig]

In this study, we have combined dielectric spectroscopy and H-2 NMR to elucidate the molecular dynamics of aqueous solutions of dipropylene glycol monomethyl ether (DiPGME) confined into 2.8 nm pores of MCM-41. The results show that the concentration dependence of the dynamics is completely different compared to the corresponding bulk solutions, where a pronounced nonmonotonic concentration dependence was observed for the glass transition and its related a-relaxation. In the confinement, both the cooperative alpha-relaxation and the more local beta-relaxation are almost unaffected by the water concentration. The main reasons for this seem to be that there is a preferential hydration of the inner pore surfaces, leading to a strong concentration gradient in the pores, as well as ice formation at higher water concentrations (45 wt % and above during heating), also leading to less water and a weaker concentration dependence in DiPGME-rich regions. The beta-process is observed in the DS measurements even for confined DiPGME, without any water. This implies that the beta-relaxation is strongly enhanced, compared to the alpha-relaxation, in the confinement, since it could not be clearly observed in the bulk liquid. A beta-relaxation due to water was observed in the bulk solutions, but this process was rapidly speeding up with increasing water concentration, while it is basically concentration independent in the confinement. From the NMR measurements, it was also possible to conclude that the a-relaxation of the confined solutions is composed of a number of consecutive small-angle elementary rotational jumps, and that the beta-process is related to a spatially restricted motion.

Nyckelord: Nuclear-Magnetic-Resonance, Organic Glass Formers, Slow Beta-Process, Confined Water, Secondary Relaxation, Supercooled Liquids, Transition, Nmr, Spectroscopy, Polymers



Denna post skapades 2017-05-08.
CPL Pubid: 249176

 

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Institutioner (Chalmers)

Institutionen för fysik, Kondenserade materiens fysik (Chalmers)

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Den kondenserade materiens fysik

Chalmers infrastruktur