Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture
Novel hierarchically structured microporous bio-carbons with exceptionally high capacities for CO2 capture have been synthesized from the abundant agricultural waste of rice husk (RH), using a facile methodology that effectively integrated carbonisation, activation and potassium intercalation into a...
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American Chemical Society
2017
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| Online Access: | https://eprints.nottingham.ac.uk/44111/ |
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| author | LIU, Xin Sun, Yuan Liu, Jingjing Sun, Chenggong Liu, Hao Xue, Qian Smith, Emily F. Snape, Colin E. |
| author_facet | LIU, Xin Sun, Yuan Liu, Jingjing Sun, Chenggong Liu, Hao Xue, Qian Smith, Emily F. Snape, Colin E. |
| author_sort | LIU, Xin |
| building | Nottingham Research Data Repository |
| collection | Online Access |
| description | Novel hierarchically structured microporous bio-carbons with exceptionally high capacities for CO2 capture have been synthesized from the abundant agricultural waste of rice husk (RH), using a facile methodology that effectively integrated carbonisation, activation and potassium intercalation into a one-step process. Textural characterisation demonstrates that the synthesized bio-carbons exhibit exceedingly high ultra-microporosity accounting for up to 95% of total porosity mainly as a result of the naturally occurring silicon compounds within the RH molecular framework structures. With a modest surface area of up to 1035 m2/g and a total pore volume of 0.43 cm3/g, the best performing RH carbon has showed exceptionally high and fully reversible CO2 uptake capacity of 2.0 mmol/g at 25 oC and a CO2 partial pressure of 0.15 bar, which represents one of the highest uptakes ever reported for both carbon and MOF materials usually prepared from using cost-prohibitive precursor materials with cumbersome methodologies. It has been found that up to 50% of the total CO2 uptake is attributable to the unique surface chemistry of the RH carbons, which appears to be dominated by the enhanced formation of extra-framework potassium cations owing to the exceedingly high levels of ultra-microporosity and the presence of zeolitic structures incorporated within the carbon matrices. Characterisations by EDX element mapping, XPS and the heat of adsorption measurements confirm the existence of a range of zeolitic structures, which essentially transforms the RH carbons into a kind of zeolite-carbon nanocomposite materials with strong surface affinity to CO2. |
| first_indexed | 2025-11-14T19:54:23Z |
| format | Article |
| id | nottingham-44111 |
| institution | University of Nottingham Malaysia Campus |
| institution_category | Local University |
| last_indexed | 2025-11-14T19:54:23Z |
| publishDate | 2017 |
| publisher | American Chemical Society |
| recordtype | eprints |
| repository_type | Digital Repository |
| spelling | nottingham-441112020-05-04T18:54:56Z https://eprints.nottingham.ac.uk/44111/ Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture LIU, Xin Sun, Yuan Liu, Jingjing Sun, Chenggong Liu, Hao Xue, Qian Smith, Emily F. Snape, Colin E. Novel hierarchically structured microporous bio-carbons with exceptionally high capacities for CO2 capture have been synthesized from the abundant agricultural waste of rice husk (RH), using a facile methodology that effectively integrated carbonisation, activation and potassium intercalation into a one-step process. Textural characterisation demonstrates that the synthesized bio-carbons exhibit exceedingly high ultra-microporosity accounting for up to 95% of total porosity mainly as a result of the naturally occurring silicon compounds within the RH molecular framework structures. With a modest surface area of up to 1035 m2/g and a total pore volume of 0.43 cm3/g, the best performing RH carbon has showed exceptionally high and fully reversible CO2 uptake capacity of 2.0 mmol/g at 25 oC and a CO2 partial pressure of 0.15 bar, which represents one of the highest uptakes ever reported for both carbon and MOF materials usually prepared from using cost-prohibitive precursor materials with cumbersome methodologies. It has been found that up to 50% of the total CO2 uptake is attributable to the unique surface chemistry of the RH carbons, which appears to be dominated by the enhanced formation of extra-framework potassium cations owing to the exceedingly high levels of ultra-microporosity and the presence of zeolitic structures incorporated within the carbon matrices. Characterisations by EDX element mapping, XPS and the heat of adsorption measurements confirm the existence of a range of zeolitic structures, which essentially transforms the RH carbons into a kind of zeolite-carbon nanocomposite materials with strong surface affinity to CO2. American Chemical Society 2017-07-11 Article PeerReviewed LIU, Xin, Sun, Yuan, Liu, Jingjing, Sun, Chenggong, Liu, Hao, Xue, Qian, Smith, Emily F. and Snape, Colin E. (2017) Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture. ACS Applied Materials & Interfaces . ISSN 1944-8244 CO2 capture carbon materials rice husk surface chemistry ultra-microporosity http://pubs.acs.org/doi/abs/10.1021/acsami.7b06665 doi:10.1021/acsami.7b06665 doi:10.1021/acsami.7b06665 |
| spellingShingle | CO2 capture carbon materials rice husk surface chemistry ultra-microporosity LIU, Xin Sun, Yuan Liu, Jingjing Sun, Chenggong Liu, Hao Xue, Qian Smith, Emily F. Snape, Colin E. Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture |
| title | Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture |
| title_full | Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture |
| title_fullStr | Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture |
| title_full_unstemmed | Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture |
| title_short | Potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for CO2 capture |
| title_sort | potassium and zeolitic structure modified ultra-microporous adsorbent materials from a renewable feedstock with favourable surface chemistry for co2 capture |
| topic | CO2 capture carbon materials rice husk surface chemistry ultra-microporosity |
| url | https://eprints.nottingham.ac.uk/44111/ https://eprints.nottingham.ac.uk/44111/ https://eprints.nottingham.ac.uk/44111/ |