Abstract
The hydrodeoxygenation of furfural (FU) was investigated over Fe-containing MgO catalysts, on a continuous gas flow reactor, using methanol as a hydrogen donor. Catalysts were prepared either by coprecipitation or impregnation methods, with different Fe/Mg atomic ratios. The main product was 2-methylfuran (MFU), an important highly added value chemical, up to 92% selectivity. The catalyst design helped our understanding of the impact of acid/base properties and the nature of iron species in terms of catalytic performance. In particular, the addition of iron on the surface of the basic oxide led to (i) the increase of Lewis acid sites, (ii) the increase of the dehydrogenation capacity of the presented catalytic system, and (iii) to the significant enhancement of the FU conversion to MFU. FTIR studies, using methanol as the chosen probe molecule, indicated that, at the low temperature regime, the process follows the typical hydrogen transfer reduction, but at the high temperature regime, methanol dehydrogenation and methanol disproportionation were both presented, whereas iron oxide promoted methanol transfer. FTIR studies were performed using furfural and furfuryl alcohol as probe molecules. These studies indicated that furfuryl alcohol activation is the rate-determining step for methyl furan formation. Our experimental results clearly demonstrate that the nature of iron oxide is critical in the efficient hydrodeoxygenation of furfural to methyl furan and provides insights toward the rational design of catalysts toward C–O bonds’ hydrodeoxygenation in the production of fuel components.
Highlights
The use of biomass, lignocellulosic materials for fuels and chemical production, aims at reducing the exploitation of non-renewable resources
[3]; this is the caseare in donors promotes a higher degree of control, especially when partially hydrogenated molecules hydrodeoxygenation (HDO)
Since iron is known to have both redox and acid–base properties [23], we focused on studying the role of Fe in the Fe/MgO catalytic system, in order to determine structure–activity relationships
Summary
The use of biomass, lignocellulosic materials for fuels and chemical production, aims at reducing the exploitation of non-renewable resources. Catalysts 2019, 9, x FOR PEER REVIEW systems involve molecular hydrogen as the reductant; at the same time, H-transfer processes, where an organic molecule an alcohol) behaves as the hydrogen donor, are a promising alternative [2]. H-transfer processes,(e.g., where an organic molecule (e.g., an alcohol) behaves as the hydrogen donor, Avoiding the use of H2 for[2]. Substrate reduction safer and more selective are a promising alternative. H2 forinduce substrate reduction could induce chemical safer and processes. The lower hydrogenating capability of most hydrogen donors promotes a higher more selective chemical processes. The lower hydrogenating capability of most hydrogen degree of control, especially when partially hydrogenated molecules are needed [3]; this is the caseare in donors promotes a higher degree of control, especially when partially hydrogenated molecules hydrodeoxygenation (HDO)
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