New insights into the mechanism of interaction between CO 2 and polymers from thermodynamic parameters obtained by in situ ATR-FTIR spectroscopy

This work reports new physical insights of the thermodynamic parameters and mechanisms of possible interactions occurring in polymers subjected to high-pressure CO 2 . ATR-FTIR spectroscopy has been used in situ to determine the thermodynamic parameters of the intermolecular interactions between CO...

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Published in:Physical chemistry chemical physics : PCCP 2016, Vol.18 (9), p.6465-6475
Main Authors: Gabrienko, Anton A., Ewing, Andrew V., Chibiryaev, Andrey M., Agafontsev, Alexander M., Dubkov, Konstantin A., Kazarian, Sergei G.
Format: Article
Language:English
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Summary:This work reports new physical insights of the thermodynamic parameters and mechanisms of possible interactions occurring in polymers subjected to high-pressure CO 2 . ATR-FTIR spectroscopy has been used in situ to determine the thermodynamic parameters of the intermolecular interactions between CO 2 and different functional groups of the polymers capable of specific interactions with sorbed CO 2 molecules. Based on the measured ATR-FTIR spectra of the polymer samples subjected to high-pressure CO 2 (30 bar) at different temperatures (300–340 K), it was possible to characterize polymer–polymer and CO 2 –polymer interactions. Particularly, the enthalpy and entropy of the formation of the specific non-covalent complexes between CO 2 and the hydroxy (–OH), carbonyl (CO) and hydroxyimino (N–OH) functional groups of the polymer samples have been measured. Furthermore, the obtained spectroscopic results have provided an opportunity for the structure of these complexes to be proposed. An interesting phenomenon regarding the behavior of CO 2 /polymer systems has also been observed. It has been found that only for the polyketone, the value of enthalpy was negative indicating an exothermic process during the formation of the CO 2 –polymer non-covalent complexes. Conversely, for the polyoxime and polyalcohol samples there is a positive enthalpy determined. This is a result of the initial polymer–polymer interactions requiring more energy to break than is released during the formation of the CO 2 –polymer complex. The effect of increasing temperature to facilitate the breaking of the polymer–polymer interactions has also been observed. Hence, a mechanism for the formation of CO 2 –polymer complexes was suggested based on these results, which occurs via a two-step process: (1) the breaking of the existing polymer–polymer interactions followed by (2) the formation of new CO 2 –polymer non-covalent interactions.
ISSN:1463-9076
1463-9084
DOI:10.1039/C5CP06431G