Mechanism of CO2 capture in nanostructured sodium amide encapsulated in porous silica

Mi Tian; Antoine Buchard; Stephen A. Wells; Yanan Fang; Laura Torrente-Murciano; Antony Nearchou; Zhili Dong; Timothy J. White; Asel Sartbaeva; Valeska P. Ting

doi:10.1016/j.surfcoat.2018.06.049

Mechanism of CO₂ capture in nanostructured sodium amide encapsulated in porous silica

Mi Tian, Antoine Buchard, Stephen A. Wells, Yanan Fang, Laura Torrente-Murciano, Antony Nearchou, Zhili Dong, Timothy J. White, Asel Sartbaeva^*, Valeska P. Ting

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

170 Downloads (Pure)

Abstract

Nanostructured sodium amide encapsulated in a porous silica gel matrix (“NaNH₂-SG”) was investigated for CO₂ capture and storage by in-situ gravimetric gas sorption. Exposure of NaNH₂-SG to CO₂ at 25 °C and 1 bar pressure resulted in ~3.6 wt% CO₂ uptake over eight sorption/desorption cycles. Over 90% of the CO₂ uptake was non-reversible due to reaction between CO₂ and NaNH₂ to form sodium carbamate, as confirmed by ¹³C and ²³Na solid-state NMR. Electronic structure calculations suggest a two-stage reaction process involving initial formation and subsequent rearrangement of the carbamate product. This research confirms the feasibility of sequential reactions of nanoparticles in a porous substrate (Na-SG to NaNH₂-SG to Na-carbamate-SG), and of CO₂ capture by NaNH₂-SG nanoparticles stabilised by encapsulation within the porous substrate. This encapsulation method could allow further hygroscopic or reactive starting reagents or compounds to be explored for CO₂ capture and long-term storage.

Original language	English
Pages (from-to)	227-233
Number of pages	7
Journal	Surface and Coatings Technology
Volume	350
Early online date	28 Jun 2018
DOIs	https://doi.org/10.1016/j.surfcoat.2018.06.049
Publication status	Published - 25 Sept 2018

Keywords

Carbon capture
Encapsulation
Porous silica
Sodium amide

ASJC Scopus subject areas

Chemistry(all)
Condensed Matter Physics
Surfaces and Interfaces
Surfaces, Coatings and Films
Materials Chemistry

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10.1016/j.surfcoat.2018.06.049Licence: None: All rights reserved

Tian_et_al_Mechanism_of_CO2_capture_in_nanostructured_sodium_amide_encapsulated_in_porous_silica_Surface_and_Coatings_Technology_2018
Tian, M. et al (2018) Mechanism of CO2 capture in nanostructured sodium amide encapsulated in porous silica, Surface and Coatings Technology, volume 350, pages 227-233, https://doi.org/10.1016/j.surfcoat.2018.06.049
Accepted author manuscript, 1.04 MBLicence: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND)

https://www.sciencedirect.com/science/article/pii/S0257897218306248Licence: None: All rights reserved

Cite this

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title = "Mechanism of CO2 capture in nanostructured sodium amide encapsulated in porous silica",

abstract = "Nanostructured sodium amide encapsulated in a porous silica gel matrix (“NaNH2-SG”) was investigated for CO2 capture and storage by in-situ gravimetric gas sorption. Exposure of NaNH2-SG to CO2 at 25 °C and 1 bar pressure resulted in ~3.6 wt% CO2 uptake over eight sorption/desorption cycles. Over 90% of the CO2 uptake was non-reversible due to reaction between CO2 and NaNH2 to form sodium carbamate, as confirmed by 13C and 23Na solid-state NMR. Electronic structure calculations suggest a two-stage reaction process involving initial formation and subsequent rearrangement of the carbamate product. This research confirms the feasibility of sequential reactions of nanoparticles in a porous substrate (Na-SG to NaNH2-SG to Na-carbamate-SG), and of CO2 capture by NaNH2-SG nanoparticles stabilised by encapsulation within the porous substrate. This encapsulation method could allow further hygroscopic or reactive starting reagents or compounds to be explored for CO2 capture and long-term storage.",

keywords = "Carbon capture, Encapsulation, Porous silica, Sodium amide",

author = "Mi Tian and Antoine Buchard and Wells, {Stephen A.} and Yanan Fang and Laura Torrente-Murciano and Antony Nearchou and Zhili Dong and White, {Timothy J.} and Asel Sartbaeva and Ting, {Valeska P.}",

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doi = "10.1016/j.surfcoat.2018.06.049",

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AU - Tian, Mi

AU - Buchard, Antoine

AU - Wells, Stephen A.

AU - Fang, Yanan

AU - Torrente-Murciano, Laura

AU - Nearchou, Antony

AU - Dong, Zhili

AU - White, Timothy J.

AU - Sartbaeva, Asel

AU - Ting, Valeska P.

PY - 2018/9/25

Y1 - 2018/9/25

N2 - Nanostructured sodium amide encapsulated in a porous silica gel matrix (“NaNH2-SG”) was investigated for CO2 capture and storage by in-situ gravimetric gas sorption. Exposure of NaNH2-SG to CO2 at 25 °C and 1 bar pressure resulted in ~3.6 wt% CO2 uptake over eight sorption/desorption cycles. Over 90% of the CO2 uptake was non-reversible due to reaction between CO2 and NaNH2 to form sodium carbamate, as confirmed by 13C and 23Na solid-state NMR. Electronic structure calculations suggest a two-stage reaction process involving initial formation and subsequent rearrangement of the carbamate product. This research confirms the feasibility of sequential reactions of nanoparticles in a porous substrate (Na-SG to NaNH2-SG to Na-carbamate-SG), and of CO2 capture by NaNH2-SG nanoparticles stabilised by encapsulation within the porous substrate. This encapsulation method could allow further hygroscopic or reactive starting reagents or compounds to be explored for CO2 capture and long-term storage.

AB - Nanostructured sodium amide encapsulated in a porous silica gel matrix (“NaNH2-SG”) was investigated for CO2 capture and storage by in-situ gravimetric gas sorption. Exposure of NaNH2-SG to CO2 at 25 °C and 1 bar pressure resulted in ~3.6 wt% CO2 uptake over eight sorption/desorption cycles. Over 90% of the CO2 uptake was non-reversible due to reaction between CO2 and NaNH2 to form sodium carbamate, as confirmed by 13C and 23Na solid-state NMR. Electronic structure calculations suggest a two-stage reaction process involving initial formation and subsequent rearrangement of the carbamate product. This research confirms the feasibility of sequential reactions of nanoparticles in a porous substrate (Na-SG to NaNH2-SG to Na-carbamate-SG), and of CO2 capture by NaNH2-SG nanoparticles stabilised by encapsulation within the porous substrate. This encapsulation method could allow further hygroscopic or reactive starting reagents or compounds to be explored for CO2 capture and long-term storage.

KW - Carbon capture

KW - Encapsulation

KW - Porous silica

KW - Sodium amide

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