Litcius/Paper detail

Ultra-low carbon dioxide emissions for biomass gasification using air with nearly 100% CO2 capture and conversion

Yuan Zhu, Jie Miao, Yuanyuan Wang, Dongliang Liu, Yingrui Zhang, Xiaotong Zhao, Jia Hu, Chunfei Wu

2024Chemical Engineering Journal29 citationsDOIOpen Access PDF

Abstract

Addressing the high CO 2 emissions from biomass gasification is crucial for enhancing the sustainability and environmental profile of this technology. This work proposes a novel approach by integrating the biomass gasification process with carbon capture and utilisation (IGCCU), to tackle the substantial challenge of traditional biomass gasification, which leads to high CO 2 emissions. Specifically, during the biomass gasification stage, this novel approach successfully captured 14.39 mmol g -1 lignin of CO 2 , based on benchmark conditions. The captured CO 2 is subsequently converted into CO during the hydrogenation stage, achieving a peak CO concentration of 1.58 %. The results reveal that maintaining a marble feeding mass of 6 g and setting the reaction temperatures for gasification, carbon capture, and hydrogenation at 500 C, 400 C, and 550 C, respectively, consistently ensures ultra-low CO 2 emissions throughout the entire process. "Ultra-low CO 2 emissions" specifically refers to the absence of CO 2 signals throughout the entirety of the IGCCU process, encompassing stages such as biomass gasification, CO 2 capture, and CO 2 conversion. Notably, CO 2 conversion and CO selectivity remain at a stable 100 % level over 8 cycles as only CO was generated during the hydrogenation stage, underscoring the excellent stability of this novel technology. Furthermore, the utilisation of low-cost sorbent material (waste marble powder) and the readily available biomass gasification agent (air) enhance the economic feasibility of this new technology while demonstrating robust resistance to carbon deposition.

Topics & Concepts

Biomass (ecology)Carbon dioxideCarbon fibersSyngasGreenhouse gasEnvironmental scienceWaste managementCarbon capture and storage (timeline)Pulp and paper industryChemistryMaterials scienceCatalysisEngineeringOrganic chemistryBiologyGeologyEcologyComposite numberOceanographyClimate changeComposite materialThermochemical Biomass Conversion ProcessesCatalysts for Methane ReformingCarbon Dioxide Capture Technologies