Details

Autor(en) / Beteiligte

• Yao, Nai-Yu
• Cao, Jing-Pei
• Zhao, Xiao-Yan
• Pang, Xin-Bo
• Zhao, Jing-Ping
• Chen, Chen-Xu
• Cai, Shi-Jie
• Feng, Xiao-Bo
• Dung Le, Duc

Titel

Coke formation on different metal-modified (Co, Mo and Zr) ZSM-5 in the catalytic pyrolysis of cellulose to light aromatics

Ist Teil von

• Journal of analytical and applied pyrolysis, 2024-05, Vol.179, p.106516, Article 106516

Ort / Verlag

Elsevier B.V

Erscheinungsjahr

2024

Link zum Volltext

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Catalytic pyrolysis of biomass is regarded as a promising method for preparing value-added products. However, the main factors limiting the development of the process at present are the low yield of value-added products and poor selectivity, especially for rapid catalyst deactivation due to coke deposition. The present study focuses on the catalytic pyrolysis of cellulose over metal Co-, Mo-, and Zr-loaded catalysts using a falling fixed bed at 600 °C to evaluate the type of coking of the catalysts as well as the effect of the different metal active sites on the formation of coke deposits. The introduction of Co and Mo metal sites increased the light aromatics yield of ZSM-5 from 128.9 mg/g to 147.2 mg/g and 143.0 mg/g. And the yield of coke deposits decreased from 8.3 to 6.8 and 5.1 wt%. The stability evaluation of the catalyst showed that the deactivation degree of ZSM-5 of the supported metal Co was lower than that of commercial ZSM-5, while the ZSM-5 of the supported metal Mo was rapidly deactivated. The deactivation of the catalysts depended more on the morphology or location of the accumulated coke than on the total amount deposited. The clogging of metal and acidic sites on the surface of the zeolite and the pore channels by the amorphous encapsulating coke was the main cause of catalyst deactivation. The metal Mo active sites promoted dehydrogenation coupling and hydrogen transfer during coke formation, forming a more highly disordered multiring structure, and the metal Co active sites were more capable of decomposing macromolecular compounds, olefins and alkanes, and promoted the formation of graphite-like structural carbon. [Display omitted] •No positive correlation between the degree of catalyst deactivation and coke yield.•Amorphous coated carbon is an important cause of catalyst deactivation.•Mo site promotes dehydrogen coupling and hydrogen transfer during coke formation.•The Co active site promotes the formation of graphite-like structural carbon on coke.