Litcius/Paper detail

Enhancing the activity of Zn, Fe, and Ni-embedded microporous biocarbon: Towards efficiently catalytic fast co-pyrolysis/gasification of lignocellulosic and plastic wastes

Xuesong Zhang, Ruolan Xu, Quan Liu, Ge Kong, Hanwu Lei, Roger Ruan, Lujia Han

2022Energy Conversion and Management X38 citationsDOIOpen Access PDF

Abstract

This study explored an energy-efficient and cost-effective method to synthesize three-dimensional metal-embedded microporous carbocatalysts. Pellet biochar manufactured with compressed and porous structure was used as the carbonaceous precursor, which was modulated by diverse metal chlorides in the single-step thermal process, fulfilling the synchronous pore-forming, metal-doping, and graphitization. The as-synthesized carbocatalysts were characterized in detail by using N2 physisorption, SEM, TEM, EDX, XRD, TPO, TGA, FTIR, XPS, Raman, CHNS elemental analysis, etc. It was found that the metal-embedded carbocatalysts possessed well-developed 3D microporous structures with the highest specific surface area of 964 m2/g. The catalytic activities of these catalysts were investigated during on-line and ex-situ catalytic fast co-pyrolysis of wheat straw and plastic waste. It was observed that the carbon yield of bio-oils could reach over 60 C% by using [email protected] as the catalyst at 500 °C, and the HHV of bio-oils peaked at 38.52 MJ/Kg in the presence of [email protected] at 500 °C. Moreover, these carbcatalysts at 500 °C favored production of hydrocarbons with a relative content up to 98%; in particular, monocyclic aromatics presented the highest selectivity (nearly 60%). Among metal-embedded carbcatalysts, [email protected] at 800 °C was in favor of H2 (157 NmL/gfeedstock) and syngas (273 NmL/gfeedstock) production; importantly, [email protected] also promoted the generation of carbon nanotubes. Additionally, the thermal degradation behaviors and kinetics of non-catalytic and catalytic co-pyrolysis of biomass and plastic waste over the as-synthesized catalysts were also tested by thermogravimetric analysis. Finally, a rational reaction mechanism regarding ex-situ catalyst fast co-pyrolysis of biomass and plastic waste over catalytically active sites on the as-synthesized catalysts was elucidated. Accordingly, this work provides a great potential of using the promising carbocatalysts to co-valorize biomass and plastic waste into the integrated harvests of monocyclic aromatics, syngas, and valuable carbons.

Topics & Concepts

PyrolysisCatalysisMicroporous materialMaterials scienceChemical engineeringBiocharPhysisorptionSyngasLignocellulosic biomassCarbon fibersNuclear chemistryChemistryOrganic chemistryLigninComposite numberComposite materialEngineeringThermochemical Biomass Conversion ProcessesCatalysis and Hydrodesulfurization StudiesLignin and Wood Chemistry