Biogas Upgrading via Cyclic CO2 Adsorption: Application of Highly Regenerable PEI@nano-Al2O3 Adsorbents with Anti-Urea Properties

Solid amine adsorbents are among the most promising CO2 adsorption technologies for biogas upgrading due to their high selectivity toward CO2, low energy consumption, and easy regeneration. However, in most cases, these adsorbents undergo severe chemical inactivation due to urea formation when regen...

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Published inEnvironmental science & technology Vol. 55; no. 8; pp. 5236 - 5247
Main Authors Shen, Xuehua, Yan, Feng, Li, Chunyan, Qu, Fan, Wang, Yingqing, Zhang, Zuotai
Format Journal Article
LanguageEnglish
Published Easton American Chemical Society 20.04.2021
Subjects
Adsorbents
Adsorption
Aluminum oxide
Amines
Atmosphere
Biogas
Carbon dioxide
Chemical modification
Crosslinking
Decay rate
Dilution
Energy and Climate
Energy consumption
Fly ash
Inactivation
Lewis acid
Polyethyleneimine
Regeneration
Selectivity
Separation processes
Synthesis
Upgrading
Urea
Ureas
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Summary:Solid amine adsorbents are among the most promising CO2 adsorption technologies for biogas upgrading due to their high selectivity toward CO2, low energy consumption, and easy regeneration. However, in most cases, these adsorbents undergo severe chemical inactivation due to urea formation when regenerated under a realistic CO2 atmosphere. Herein, we demonstrated a facile and efficient synthesis route, involving the synthesis of nano-Al2O3 support derived from coal fly ash with a CO2 flow as the precipitant and the preparation of polyethylenimine (PEI)-impregnated Al2O3-supported adsorbent. The optimal 55%PEI@2%Al2O3 adsorbent showed a high CO2 uptake of 139 mg·g–1 owing to the superior pore structure of synthesized nano-Al2O3 support and exhibited stable cyclic stability with a mere 0.29% decay per cycle even under the realistic regenerated CO2 atmosphere. The stabilizing mechanism of PEI@nano-Al2O3 adsorbent was systematically demonstrated, namely, the cross-linking reaction between the amidogen of a PEI molecule and nano-Al2O3 support, owing to the abundant Lewis acid sites of nano-Al2O3. This cross-linking process promoted the conversion of primary amines into secondary amines in the PEI molecule and thus significantly enhanced the cyclic stability of PEI@nano-Al2O3 adsorbents by markedly inhibiting the formation of urea compounds. Therefore, this facile and efficient strategy for PEI@nano-Al2O3 adsorbents with anti-urea properties, which can avoid active amine content dilution from PEI chemical modification, is promising for practical biogas upgrading and various CO2 separation processes.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.0c07973