Ojus Mohan scite author profile

Catalytic hydrodeoxygenation of fast pyrolysis bio-oils is a potential approach for producing green fuels. This process requires active and inexpensive catalysts with bifunctionality favoring C−O bond scission under high pressure (145−2900 psig) and temperature (350−500 °C) conditions. In this context, metal carbides are promising candidates for the selective deoxygenation of oxygenated compounds. The understanding of their active sites and mechanism is however limited. In the present work, the electronic interaction between Mo and W in their mixed carbide and its effect on the energetics and mechanism of guaiacol hydrodeoxygenation (HDO) were explored by using experiments and first-principles density functional theory calculations. Experimentally, CO and H 2 were used as probe molecules in pulse chemisorption to identify the different natures of active sites in metal carbides. The calculated binding energies and adsorption configurations available for CO and H atoms on the surface of the catalysts describe their different adsorption capacities. Regarding the deoxygenation reaction, our calculations showed that oxygen bonded ∼1 eV stronger on the bimetallic carbide (MoWC) than on the monometallic molybdenum carbide surface, confirming the enhanced oxophillicity of carbides in the presence of W. The observed preferential selectivity toward deoxygenated products in the HDO of guaiacol on MoWC surfaces was further explained by the mechanistic investigation of MoWC and Mo 2 C surfaces. Our calculations indicated that the direct deoxygenation (DDO) pathway was kinetically favored on the bimetallic MoWC surface (leading to benzene) because of its high oxophilicity, while the hydrogenation−dehydration and DDO pathways proceeded with competitive barriers on Mo 2 C.

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Predicting CO₂ adsorption and reactivity on transition metal surfaces using popular density functional theory methods

Mohan

Trịnh

Banerjee

et al. 2019

Molecular Simulation

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Ojus Mohan

Investigating methane dry reforming on Ni and B promoted Ni surfaces: DFT assisted microkinetic analysis and addressing the coking problem

A Combined Experimental and DFT Investigation of Selective Hydrodeoxygenation of Guaiacol over Bimetallic Carbides

Predicting CO₂ adsorption and reactivity on transition metal surfaces using popular density functional theory methods

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Ojus Mohan

Investigating methane dry reforming on Ni and B promoted Ni surfaces: DFT assisted microkinetic analysis and addressing the coking problem

A Combined Experimental and DFT Investigation of Selective Hydrodeoxygenation of Guaiacol over Bimetallic Carbides

Predicting CO2 adsorption and reactivity on transition metal surfaces using popular density functional theory methods

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Predicting CO₂ adsorption and reactivity on transition metal surfaces using popular density functional theory methods