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Article Abstract
FeOOH polymorphs are valued in industrial catalysis for selective hydrogenation of organics in coal to high - value aromatics, yet the factors behind their differing efficiencies are still unclear. In this work, the synthesis of FeOOH nanopolymorphs with sizes from 80 to 300 nm was achieved through a simple, efficient, and environmentally friendly room temperature solid-phase chemical reaction. FeOOH polymorphs demonstrate different iron oxidation states and abundant surface hydroxyls. Among them, δ-FeOOH, with its lower iron oxidation state and rich surface hydroxyls, enhances hydrogen adsorption and lowers hydrogen activation energy through hydrogen bonding. Notably, δ-FeOOH achieved the complete conversion of benzyl phenyl ether, a typical α-O-4 linkage model compound in coal at 270 °C and 20 bar H for 2 h. This study provides valuable insights into the intricate relationship between FeOOH polymorphs and catalytic performance, contributing to the sustainable development of FeOOH-based hydrogenation catalysts.
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| http://dx.doi.org/10.1021/acs.inorgchem.5c00543 | DOI Listing |
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