Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates

Khodabakhshi, Saeid; Taddei, Marco; Rudd, Jennifer; McPherson, Matthew; Niu, Yubiao; Palmer, Richard; Barron, Andrew; Andreoli, Enrico

doi:10.1016/j.carbon.2020.11.080

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Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates

Saeid Khodabakhshi, Marco Taddei

, Jennifer Rudd

, Matthew McPherson

, Yubiao Niu, Richard Palmer

, Andrew Barron

, Enrico Andreoli

Carbon, Volume: 173, Pages: 989 - 1002

Swansea University Authors: Saeid Khodabakhshi, Marco Taddei , Jennifer Rudd , Matthew McPherson , Yubiao Niu, Richard Palmer , Andrew Barron , Enrico Andreoli

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DOI (Published version): 10.1016/j.carbon.2020.11.080

Abstract

Microporous carbons were prepared starting from a series of benzene polycarboxylic acids following two strategies: (i) activation- and template-free pyrolysis and (ii) ion-exchange pyrolysis. The proposed synthetic strategies are facile approaches to produce highly microporous carbons that avoid the...

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Published in:	Carbon
ISSN:	0008-6223
Published:	Elsevier BV 2021
Online Access:	Check full text
URI:	https://cronfa.swan.ac.uk/Record/cronfa55810
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first_indexed	2020-12-03T09:48:19Z
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The proposed synthetic strategies are facile approaches to produce highly microporous carbons that avoid the use of large amounts of corrosive and expensive chemical activators or templates. By varying the number of carboxylic acid groups, the charge balancing species and the degree of deprotonation of the precursors, microporous carbons with diverse morphologies, textural properties and oxygen contents were obtained and their CO2 and N2 sorption properties were assessed. The abundant micropores made the materials suitable for CO2 adsorption at low pressure and ambient temperature, achieving CO2 uptake as high as 4.4 mmol/g at 25 °C and 1 bar, competitive with those reported for porous carbons produced using large excess of alkali metal based activating agents. It was found that high performance, in terms of CO2 uptake and CO2/N2 selectivity, was linked to the simultaneous presence of large ultra-micropore volume and high oxygen content in the sorbents. 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spelling	2021-02-15T15:53:41.8588880 v2 55810 2020-12-03 Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates 547fd5929a2fd30733277eca799fbf9b Saeid Khodabakhshi Saeid Khodabakhshi true false 5cffd1038508554d8596dee8b4e51052 0000-0003-2805-6375 Marco Taddei Marco Taddei true false c2e4cf0f048a86b5ca2f331e6c566aff 0000-0002-5209-477X Jennifer Rudd Jennifer Rudd true false 69886ed1df27345672e1a52ddee565fe 0000-0002-7529-5355 Matthew McPherson Matthew McPherson true false c403a40f2acf2dc32e37b4555d19b4c0 Yubiao Niu Yubiao Niu true false 6ae369618efc7424d9774377536ea519 0000-0001-8728-8083 Richard Palmer Richard Palmer true false 92e452f20936d688d36f91c78574241d 0000-0002-2018-8288 Andrew Barron Andrew Barron true false cbd843daab780bb55698a3daccd74df8 0000-0002-1207-2314 Enrico Andreoli Enrico Andreoli true false 2020-12-03 CHEG Microporous carbons were prepared starting from a series of benzene polycarboxylic acids following two strategies: (i) activation- and template-free pyrolysis and (ii) ion-exchange pyrolysis. The proposed synthetic strategies are facile approaches to produce highly microporous carbons that avoid the use of large amounts of corrosive and expensive chemical activators or templates. By varying the number of carboxylic acid groups, the charge balancing species and the degree of deprotonation of the precursors, microporous carbons with diverse morphologies, textural properties and oxygen contents were obtained and their CO2 and N2 sorption properties were assessed. The abundant micropores made the materials suitable for CO2 adsorption at low pressure and ambient temperature, achieving CO2 uptake as high as 4.4 mmol/g at 25 °C and 1 bar, competitive with those reported for porous carbons produced using large excess of alkali metal based activating agents. It was found that high performance, in terms of CO2 uptake and CO2/N2 selectivity, was linked to the simultaneous presence of large ultra-micropore volume and high oxygen content in the sorbents. This suggests that the interplay of ultra-microporosity and oxygen doping matters more than the two features taken singularly in determining the CO2/N2 separation properties of porous carbons at low pressure. Journal Article Carbon 173 989 1002 Elsevier BV 0008-6223 Porous carbons, carbon capture, ultra-microporosity, oxygen doping 1 3 2021 2021-03-01 10.1016/j.carbon.2020.11.080 COLLEGE NANME Chemical Engineering COLLEGE CODE CHEG Swansea University 2021-02-15T15:53:41.8588880 2020-12-03T09:45:39.8880235 Faculty of Science and Engineering School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Mechanical Engineering Saeid Khodabakhshi 1 Marco Taddei 0000-0003-2805-6375 2 Jennifer Rudd 0000-0002-5209-477X 3 Matthew McPherson 0000-0002-7529-5355 4 Yubiao Niu 5 Richard Palmer 0000-0001-8728-8083 6 Andrew Barron 0000-0002-2018-8288 7 Enrico Andreoli 0000-0002-1207-2314 8 55810__18799__38192a34c7ad4fcbb42838c87eacb698.pdf 55810.pdf 2020-12-03T09:47:52.4494686 Output 3560614 application/pdf Accepted Manuscript true 2021-12-01T00:00:00.0000000 ©2020 All rights reserved. All article content, except where otherwise noted, is licensed under a Creative Commons Attribution Non-Commercial No Derivatives License (CC-BY-NC-ND) true eng http://creativecommons.org/licenses/by-nc-nd/4.0/
title	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates
spellingShingle	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates Saeid Khodabakhshi Marco Taddei Jennifer Rudd Matthew McPherson Yubiao Niu Richard Palmer Andrew Barron Enrico Andreoli
title_short	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates
title_full	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates
title_fullStr	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates
title_full_unstemmed	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates
title_sort	Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates
author_id_str_mv	547fd5929a2fd30733277eca799fbf9b 5cffd1038508554d8596dee8b4e51052 c2e4cf0f048a86b5ca2f331e6c566aff 69886ed1df27345672e1a52ddee565fe c403a40f2acf2dc32e37b4555d19b4c0 6ae369618efc7424d9774377536ea519 92e452f20936d688d36f91c78574241d cbd843daab780bb55698a3daccd74df8
author_id_fullname_str_mv	547fd5929a2fd30733277eca799fbf9b_*_Saeid Khodabakhshi 5cffd1038508554d8596dee8b4e51052__Marco Taddei c2e4cf0f048a86b5ca2f331e6c566aff__Jennifer Rudd 69886ed1df27345672e1a52ddee565fe__Matthew McPherson c403a40f2acf2dc32e37b4555d19b4c0__Yubiao Niu 6ae369618efc7424d9774377536ea519__Richard Palmer 92e452f20936d688d36f91c78574241d__Andrew Barron cbd843daab780bb55698a3daccd74df8_*_Enrico Andreoli
author	Saeid Khodabakhshi Marco Taddei Jennifer Rudd Matthew McPherson Yubiao Niu Richard Palmer Andrew Barron Enrico Andreoli
author2	Saeid Khodabakhshi Marco Taddei Jennifer Rudd Matthew McPherson Yubiao Niu Richard Palmer Andrew Barron Enrico Andreoli
format	Journal article
container_title	Carbon
container_volume	173
container_start_page	989
publishDate	2021
institution	Swansea University
issn	0008-6223
doi_str_mv	10.1016/j.carbon.2020.11.080
publisher	Elsevier BV
college_str	Faculty of Science and Engineering
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hierarchy_parent_title	Faculty of Science and Engineering
department_str	School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Mechanical Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Mechanical Engineering
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description	Microporous carbons were prepared starting from a series of benzene polycarboxylic acids following two strategies: (i) activation- and template-free pyrolysis and (ii) ion-exchange pyrolysis. The proposed synthetic strategies are facile approaches to produce highly microporous carbons that avoid the use of large amounts of corrosive and expensive chemical activators or templates. By varying the number of carboxylic acid groups, the charge balancing species and the degree of deprotonation of the precursors, microporous carbons with diverse morphologies, textural properties and oxygen contents were obtained and their CO2 and N2 sorption properties were assessed. The abundant micropores made the materials suitable for CO2 adsorption at low pressure and ambient temperature, achieving CO2 uptake as high as 4.4 mmol/g at 25 °C and 1 bar, competitive with those reported for porous carbons produced using large excess of alkali metal based activating agents. It was found that high performance, in terms of CO2 uptake and CO2/N2 selectivity, was linked to the simultaneous presence of large ultra-micropore volume and high oxygen content in the sorbents. This suggests that the interplay of ultra-microporosity and oxygen doping matters more than the two features taken singularly in determining the CO2/N2 separation properties of porous carbons at low pressure.
published_date	2021-03-01T04:10:17Z
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Interplay between oxygen doping and ultra-microporosity improves the CO2/N2 separation performance of carbons derived from aromatic polycarboxylates

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