Issue 15, 2021

Adsorption-based membranes for air separation using transition metal oxides

Abstract

In this work, we use computational modeling to examine the viability of adsorption-based pore-flow membranes for separating gases when a purely size-based separation strategy is ineffective. Using molecular dynamics simulations of O2 and N2, we model permeation through a nanoporous graphene membrane. Permeation is assumed to follow a five-step adsorption-based pathway, with desorption being the rate-limiting step. Using this model, we observe increased selectivity between O2 and N2, resulting from increased adsorption energy differences. We explore the limits of this strategy, providing an initial set of constraints that need to be satisfied to allow for selectivity. Finally, we provide a preliminary exploration of some transition metal oxides that appear to satisfy those conditions. Using density functional theory calculations, we confirm that these oxides possess adsorption energies needed to operate as adsorption-based pore-flow membranes. These adsorption energies provide a suitable motivation to examine adsorption-based pore-flow membranes as a viable option for air separation.

Graphical abstract: Adsorption-based membranes for air separation using transition metal oxides

Supplementary files

Article information

Article type
Paper
Submitted
26 Apr 2021
Accepted
25 Jun 2021
First published
25 Jun 2021
This article is Open Access
Creative Commons BY license

Nanoscale Adv., 2021,3, 4502-4512

Adsorption-based membranes for air separation using transition metal oxides

A. Jana, D. S. Bergsman and J. C. Grossman, Nanoscale Adv., 2021, 3, 4502 DOI: 10.1039/D1NA00307K

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