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H$_2$O and CO$_2$ sorption in ion exchange sorbents: distinct interactions in amine versus quaternary ammonium materials

Published 5 Aug 2025 in physics.chem-ph and cond-mat.mtrl-sci | (2508.03909v1)

Abstract: This study investigates the H$_2$O and CO$_2$ sorption behavior of two ion exchange sorbents: a primary amine and a permanently charged strong base quaternary ammonium (QA) groups with (bi)carbonate counter-anions. We compare their distinct interactions with H$_2$O and CO$_2$ through simultaneous thermal gravimetric, calorimetric, gas analysis and molecular modeling to evaluate their performance for dilute CO$_2$ separations like direct air capture. Thermal and hybrid (heat + low-temperature hydration) desorption experiments demonstrate that the QA-based sorbent binds both water and CO$_2$ more strongly than the amine counterparts but undergoes degradation at moderate temperatures, limiting its compatibility with thermal swing regeneration. However, a low-temperature moisture-driven regeneration pathway at is uniquely effective for the QA-based sorbent. To inform the energetics of a moisture-based CO$_2$ separation, we compare calorimetric water sorption enthalpies to isosteric enthalpies. To our knowledge, this includes the first direct measurement of water sorption enthalpy in the QA-based sorbent. Molecular modeling supports this observation, showing higher water sorption energies and denser charge distributions in the QA-based sorbent. Mixed gas experiments in QA-based sorbent show that not only does water influence CO$_2$ binding, but CO$_2$ influences water uptake through counterion-dependent hydration states, and that moisture swing responsiveness in this material causes hydration-induced CO$_2$ release and drying-induced CO$_2$ uptake, an important feature for low-energy CO$_2$ separation under ambient conditions. Overall, the two classes of sorbents offer distinct pathways for CO$_2$ separation. Primary amine-based sorbent relies on weaker hydrogen bonding and CO$_2$-amine interactions, while QA-based sorbent leverages stronger electrostatic coupling between water and QA-reactive anion pairs.

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