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Design of Ultra-Stable Solid Amine Adsorbents and Mechanisms of Hydroxyl Group-Dependent Deactivation for Reversible CO2 Capture from Flue Gas

Meng Zhao, Liang Huang, Yanshan Gao, Ziling Wang, Shuyu Liang, Xuancan Zhu, Qiang Wang, Hong He, Dermot O’Hare

2025Nano-Micro Letters30 citationsDOIOpen Access PDF

Abstract

Abstract Although supported solid amine adsorbents have attracted great attention for CO 2 capture, critical chemical deactivation problems including oxidative degradation and urea formation have severely restricted their practical applications for flue gas CO 2 capture. In this work, we reveal that the nature of surface hydroxyl groups (metal hydroxyl Al–OH and nonmetal hydroxyl Si–OH) plays a key role in the deactivation mechanisms. The polyethyleneimine (PEI) supported on Al–OH-containing substrates suffers from severe oxidative degradation during the CO 2 capture step due to the breakage of amine-support hydrogen bonding networks, but exhibits an excellent anti-urea formation feature by preventing dehydration of carbamate products under a pure CO 2 regeneration atmosphere. In contrast, PEI supported on Si–OH-containing substrates exhibits excellent anti-oxidative stability under simulated flue gas conditions by forming a robust hydrogen bonding protective network with Si–OH, but suffers from obvious urea formation during the pure CO 2 regeneration step. We also reveal that the urea formation problem for PEI-SBA-15 can be avoided by the incorporation of an OH-containing PEG additive. Based on the intrinsic understanding of degradation mechanisms, we successfully synthesized an adsorbent 40PEI-20PEG-SBA-15 that demonstrates outstanding stability and retention of a high CO 2 capacity of 2.45 mmol g −1 over 1000 adsorption–desorption cycles, together with negligible capacity loss during aging in simulated flue gas (10% CO 2 + 5% O 2 + 3% H 2 O) for one month at 60–70 °C. We believe this work makes great contribution to the advancement in the field of ultra-stable solid amine-based CO 2 capture materials.

Topics & Concepts

ChemistryAdsorptionFlue gasAmine gas treatingDegradation (telecommunications)Hydrogen bondUreaChemical engineeringInorganic chemistryOrganic chemistryMoleculeTelecommunicationsComputer scienceEngineeringCarbon Dioxide Capture TechnologiesMembrane Separation and Gas TransportCovalent Organic Framework Applications
Design of Ultra-Stable Solid Amine Adsorbents and Mechanisms of Hydroxyl Group-Dependent Deactivation for Reversible CO2 Capture from Flue Gas | Litcius