Nanostructured Carbon Material Effect on the Synthesis of Carbon-Supported Molybdenum Carbide Catalysts for Guaiacol Hydrodeoxygenation

Abstract: The impact of using different nanostructured carbon materials (carbon nanofibers, carbon nanotubes, graphene oxide and activated carbon) as a support for Mo2C-based catalysts on the hydrodeoxygenation (HDO) of guaiacol was studied. To optimise the catalyst preparation by carbothermal hydrogen reduction (CHR), a thermogravimetric study was conducted to select the optimum CHR temperature for each carbon material, considering both the crystal size of the resulting β-Mo2C particles and the extent of the support ga… Show more

“…42-1120), 31 Mo 2 C (JCPDS No. 35-0787), 32 and MoC 2 O 4 33 species can be detected, which is due to the carbothermic reduction reaction and the reaction of carbon with MoO 3 , respectively. The formation of the CoO phase originates from the carbonization of ZIF-67.…”

Interfacial engineering and chemical reconstruction of Mo/Mo₂C@CoO@NC heterostructure for promoting oxygen evolution reaction

“…42-1120), 31 Mo 2 C (JCPDS No. 35-0787), 32 and MoC 2 O 4 33 species can be detected, which is due to the carbothermic reduction reaction and the reaction of carbon with MoO 3 , respectively. The formation of the CoO phase originates from the carbonization of ZIF-67.…”

Interfacial engineering and chemical reconstruction of Mo/Mo₂C@CoO@NC heterostructure for promoting oxygen evolution reaction

“…Under the same conditions, the active order was Mo 2 C/CNF > Mo 2 C/AC > Mo 2 C/RGO > Mo 2 C/CNT (Table 2, entries 4–7). 69 As seen from the result of XPS and N 2 physisorption, the highest HDO activity of Mo 2 C/CNF is associated with not only the highest concentration of Mo 2+ and Mo δ + (2 < δ < 3) species on the catalyst surface but also the dispersion of active sites into meso- and macropores. This is inseparable from the higher thermal stability of CNF.…”

“…70 In the case of Mo 2 C/AC, the lower surface active Mo contents and microporous nature of AC may account for the lower catalytic activity as compared to Mo 2 C/CNF, despite the larger amount of Mo. 69 The H 3 PO 4 activated biochar is more efficient for guaiacol conversion than commercial AC (Table 2, entries 9 and 10) 72 due to the acidic groups introduced into the surface of biochar by H 3 PO 4 acidification, such as hydroxyl and carboxyl groups, that promoted the conversion of guaiacol into phenol. However, these acidic groups seem to be not stable for continuous use as a catalyst.…”

Supported transition metal (Mo, W) carbide and nitride catalysts for lignin hydrodeoxygenation: interplay of supports, structure, and catalysis

Nickel promoter effect in rhenium catalysts for valorization of bio-oil model molecules