On the transport of CO$_2$ through humidified facilitated transport membranes

TL;DR

This study combines experimental and quantum-mechanical simulations to understand how water facilitates CO$_2$ transport in novel facilitated transport membranes, revealing the critical role of water in enhancing permeation.

Contribution

It provides new molecular insights into CO$_2$ transport mechanisms in facilitated membranes, highlighting water's essential role and the effects of membrane composition.

Findings

Water is essential for CO$_2$ transport in FTMs.

Mixed PVAm and MEA enhances transport performance.

Transport is fastest at low water content, ceasing without water.

Abstract

Membrane-based CO$_2$ removal from exhaust streams has recently gained much attention as a means of reducing emissions and limiting climate change. Novel membranes for CO$_2$ removal include so called facilitated transport membranes (FTMs), which offer very high selectivities for CO$_2$ while maintaining decent permeabilities. Recently, these FTMs have been scaled up from laboratory level to plant-sized pilot modules with promising results. However, the molecular details of CO$_2$ transport in these has not yet been fully unraveled. In this work, experimental studies were combined with quantum-mechanical ab initio molecular dynamics simulations to gain insight into the underlying molecular mechanism of CO$_2$ permeation through FTMs. Various compositions of polyvinyl alcohol (PVA) as the membrane matrix with polyvinyl amine (PVAm), monoethanolamine (MEA), or 4-amino-1-butanol (BA) as carrier molecules were experimentally tested. Our experiments revealed that water was essential for the CO$_2$ transport and a transport superposition was achieved with a mixed composition of PVAm and MEA in PVA. Furthermore, sorption measurements with PVA were conducted with humidified N$_2$ and CO$_2$ to quantify water sorption-induced swelling and its contribution to the gas uptake. As the carbonic acid--amine interaction is assumed to cause transport facilitation, electronic structure-based ab initio molecular dynamics simulations were conducted to study the transport of CO$_2$ in the form of carbonic acid along PVAm polymer chains. In particular, the necessity of local water for transport facilitation was studied at different water contents. The simulations show that transport is fastest in the system with low water content and does not happen in the absence of water.