Investigation on the catalytic performance of magnetic copper ferrite nanoparticles in the catalytic hydroconversion of Hanglaiwan long flame coal

•CuFe2O4 is a multifunctional composite material with excellent magnetic recovery characteristic and hydroconversion activity.•The synergic transfer of the active species produced by activating of H2 over CuFe2O4 can effectively cleave the > C-O- bridged bonds.•More valuable soluble portion can b...

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Bibliographic Details
Published in:Fuel (Guildford) 2023-12, Vol.353, p.129173, Article 129173
Main Authors: Gao, Yong, Qin, Wen-Xian, Bai, Jin-Jun, Zhu, Qi-Yang, Li, Xia-Long, Liu, Guang-Hui, Wei, Xian-Yong, Kang, Yu-Hong, Li, Yan-Jun, Ma, Xiang-Rong, Zong, Zhi-Min
Format: Article
Language:English
Subjects:
C-O- bridged bonds
Catalytic hydroconversion
CuFe2O4
Hanglaiwan long flame coal
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Summary:•CuFe2O4 is a multifunctional composite material with excellent magnetic recovery characteristic and hydroconversion activity.•The synergic transfer of the active species produced by activating of H2 over CuFe2O4 can effectively cleave the > C-O- bridged bonds.•More valuable soluble portion can be obtained in the catalytic hydroconversion of Hanglaiwan long flame coal.•After introducing CuFe2O4, the CH– and nitrogen-containing species increase, while the O2-O4 class species decrease significantly. Magnetic copper ferrite (CuFe2O4) was prepared by hydrothermal synthesis method and used for the catalytic hydroconversion (CHC) of Hanglaiwan long flame coal (HLFC) in cyclohexane under 1 MPa of initial hydrogen pressure (IHP) at 300 °C for 4 h. The total yield of soluble portion (SP) from the CHC is 33.7 wt%, significantly being higher than that (10.5 wt%) from the non-CHC (NCHC) under the same conditions. The main compounds detected in SPCHC (for CHC) are arenes and oxygen-containing organic compounds (OCOCs). Benzyloxybenzene (BOB), 2-(benzyloxy)naphthalene (BON), oxybis(methylene)dibenzene (OBMDB), oxydibenzene (ODB), and 2,2′-oxydinaphthalene (ODN) were used as HLFC-related model compounds to investigate the catalytic activity of CuFe2O4 and understand the CHC mechanism of HLFC. According to the model reactions, CuFe2O4 activates H2 to biatomic active hydrogen (H…H) and splits H…H to mobile H+ and immobile H-. H+ addition to oxygen atoms (OAs) in >C-O- bridged bonds (BBs) cleaves the BBs and releases SP during the CHC of HLFC.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2023.129173