High-Capacity, Reversible, and Energy-Efficient Water Vapor Sorption by Hierarchical Micro-to-Macroporous Carbon Aerogels from Polybenzoxazine and Polybenzodiazine

Author

Vaibhav A. Edlabadkar
Rushi U. Soni
Stephen Y. Owusu
A. B.M.Shaheen ud Doulah
Nicholas Leventis, Missouri University of Science and TechnologyFollow
Chariklia Sotiriou-Leventis, Missouri University of Science and TechnologyFollow

Abstract

Quantitative, reversible water vapor sorption is in rising demand for applications ranging from home appliances to atmospheric water harvesting. However, most sorbents suffer from low water-uptake capacities, nonreusability, and especially high regeneration temperatures. This study addresses this challenge by introducing polybenzoxazine- (PBO) and polybenzodiazine-derived (PBDAZ) carbon aerogels as reversible high-capacity desiccants. PBO and PBDAZ aerogels were prepared from structurally related monomers via HCl-catalyzed ring opening polymerization. Both types of aerogels were first aromatized at 200–240 °C under air or O2 and then were carbonized at 800 °C under Ar. These as-prepared carbon aerogels were further etched at 1000 °C under flowing CO₂. Both as-prepared and CO₂-etched carbon aerogels were characterized with CHN elemental analysis, XPS, and gas (N₂and CO₂) sorption porosimetry. Their water-uptake capacity was assessed at 273, 298, and 313 K. The long-term performance and cycling stability of these aerogels were studied by switching their surrounding environment between a highly humid and a dry atmosphere (99% and 10% relative humidity, respectively), staying for 24 h in each environment. No performance deterioration was detected after 50 full cycles (100 days). Carbon aerogels from both PBDAZ and PBO showed significant water-uptake capacities (43% and 42% w/w, respectively). However, CO2-etched PBDAZ- and PBO-derived carbon aerogels showed among the highest water uptake capacities reported in the literature, reaching 117% w/w and 140% w/w at 298 K, respectively (all values at 298 K). Water uptake started with hydrogen bonding to the O and N lining the concave surfaces of the pores and continued until micropores and mesopores were filled with water. Adsorbed water was released quantitatively at room temperature just by reducing the relative humidity of the environment.

Recommended Citation

V. A. Edlabadkar et al., "High-Capacity, Reversible, and Energy-Efficient Water Vapor Sorption by Hierarchical Micro-to-Macroporous Carbon Aerogels from Polybenzoxazine and Polybenzodiazine," ACS Applied Materials and Interfaces, vol. 17, no. 35, pp. 49829 - 49841, American Chemical Society, Sep 2025.

The definitive version is available at https://doi.org/10.1021/acsami.5c10789

Department(s)

Chemistry

Comments

Tufts University, Grant CMMI-1530603

Keywords and Phrases

carbon aerogels; desiccant; reversible; room temperature; water uptake

International Standard Serial Number (ISSN)

1944-8252; 1944-8244

Document Type

Article - Journal

Document Version

Citation

File Type

text

Language(s)

English

Rights

© 2025 American Chemical Society, All rights reserved.

Publication Date

03 Sep 2025

PubMed ID

40852957