Issue 17, 2024

High-throughput design of complex oxides as isothermal, redox-activated CO2 sorbents for green hydrogen generation

Abstract

Sorption-enhanced reforming and gasification (SERG) offers a promising approach to intensify hydrogen production from carbonaceous feedstocks. However, conventional sorbents require substantial temperature increases for the endothermic CO2 release step and are prone to deactivation. This study introduces a new class of redox-activated sorbents capable of stable isothermal operation and tunable heats of reactions, thereby facilitating an efficient reactive separation scheme. Using plane-wave density functional theory (DFT) calculations of structures and free energies, we screened 1225 perovskite-structured sorbent candidates, followed with extensive experimental validation. An effective descriptor, (ΔGabs + ΔGreg), was identified to expedite sorbent optimization. The advanced sorbents showed reversible, isothermal carbonation of up to 78% of the A-site cation, permitting isothermal SERG or “iSERG”. Their versatility was demonstrated in a fluidized bed for woody biomass gasification and a packed bed for biogas conversion, yielding hydrogen-enriched (73 vol%) syngas from biomass and 95+% pure H2 from biogas. Our results also support integrated CO2 capture to produce carbon-negative hydrogen products.

Graphical abstract: High-throughput design of complex oxides as isothermal, redox-activated CO2 sorbents for green hydrogen generation

Supplementary files

Article information

Article type
Paper
Submitted
16 may 2024
Accepted
24 iyl 2024
First published
25 iyl 2024
This article is Open Access
Creative Commons BY license

Energy Environ. Sci., 2024,17, 6279-6290

High-throughput design of complex oxides as isothermal, redox-activated CO2 sorbents for green hydrogen generation

R. Cai, K. Yang, X. Wang, M. Rukh, A. S. Bosari, E. Giavedoni, A. Pierce, L. Brody, W. Tang, P. R. Westmoreland and F. Li, Energy Environ. Sci., 2024, 17, 6279 DOI: 10.1039/D4EE02119C

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