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CO<sub>2</sub> Uptake by Microporous Carbon Aerogels Derived from Polybenzoxazine and Analogous All-Nitrogen Polybenzodiazine Aerogels

Vaibhav A. Edlabadkar, Rushi U. Soni, A. B. M. Shaheen ud Doulah, Stephen Yaw Owusu, Samuel Hackett, Joshua Bartels, Nicholas Leventis, Chariklia Sotiriou‐Leventis

2024Chemistry of Materials22 citationsDOI

Abstract

The rapid rise of carbon dioxide in the atmosphere contributes to global warming and ocean acidification. Carbon capture is considered essential for keeping the atmospheric CO 2 levels from rising further. This work addresses the question of whether nitrogen or oxygen lining of the surfaces of carbon-based CO 2 absorbers is more efficient for CO 2 capture. Polybenzodiazine (PBDAZ) aerogels are carbon-aerogel precursors that were prepared recently (2023) as all-nitrogen structural analogues to well-known polybenzoxazine (PBO) aerogels. However, owing to the fact that the carbonization chemistries of both PBO and PBDAZ aerogels require a prior oxidative aromatization step in air at around 200–240 °C, both types of the resulting carbon (C) aerogels contained both oxygen and nitrogen in their structures. As a carryover from their polymeric aerogel precursors, C-PBDAZ aerogels included a higher weight percent of N (7–11%) relative to the C-PBO aerogels (5.2–5.7%) while both types of carbons included about the same amount of O (7–9%). Activation (etching) with CO 2 at 1000 °C removed more N than O, so the resulting etched carbon aerogels from either source (EC-PBDAZ or EC-PBO) contained about 8–9% of O and only 3.0–3.6% N. Postetching, most oxygen was situated in pyridonic and nitroxide sites (by XPS). Looking at the PBDAZ- and PBO-derived C and EC aerogels independently, whenever processing increased the O/N ratio within each material, the CO 2 uptake (at 273 K, 1 bar) also increased, reaching 11.5 mmol g –1 in EC-PBDAZ and 4.6 mmol g –1 in EC-PBO aerogels, starting from 7.0 mmol g –1 by C-PBDAZ and 3.0 mmol g –1 by C-PBO. Subsequently, by eliminating the relative pore volumes and surface areas as causing the different CO 2 uptakes by the two types of materials, the highest CO 2 uptake by the EC-PBDAZ aerogels was attributed to the pore sizes (diameters in the 3–4 nm range) in combination with the geometry of the CO 2 -surface adducts. EC-PBDAZ carbon aerogels showed high selectivity for CO 2 versus H 2 (up to 404:1─relevant to precombustion CO 2 capture) and high selectivity for CO 2 versus N 2 (up to 48:1─relevant to postcombustion CO 2 capture).

Topics & Concepts

AerogelCarbon fibersNitrogenCarbonizationMicroporous materialMaterials scienceOxygenChemical engineeringCarbon dioxideInorganic chemistryChemistryAdsorptionNanotechnologyOrganic chemistryComposite materialComposite numberEngineeringCovalent Organic Framework ApplicationsAerogels and thermal insulationCarbon dioxide utilization in catalysis
CO<sub>2</sub> Uptake by Microporous Carbon Aerogels Derived from Polybenzoxazine and Analogous All-Nitrogen Polybenzodiazine Aerogels | Litcius