Catalytic deactivation due to agglomeration and metal particle growth has motivated the
researchers around the globe to encapsulate the active metal particles into protective shells …

This comprehensive critical review combines, for the first time, recent advances in nanoscale
surface chemistry, surface science, DFT, adsorption calorimetry, and in situ XRD and TEM to …

A series of novel CoFe‐based catalysts are successfully fabricated by hydrogen reduction of
CoFeAl layered‐double‐hydroxide (LDH) nanosheets at 300–700° C. The chemical …

The decomposition of cobalt carbide (Co2C) to metallic cobalt in CO2 hydrogenation results
in a notable drop in the selectivity of valued C2+ products, and the stabilization of Co2C …

Biofuel or biochemical production from biomass, especially lignocellulosic biomass, is the
most promising option to replace fossil-based products to achieve sustainability. However …

The development of new catalysts for energy technology and environmental remediation
requires a thorough knowledge of how the physical and chemical properties of a catalyst …

The high-efficiency reduction of carbon dioxide (CO 2) to high value-added compounds is of
paramount importance for ameliorating energy shortage and reducing greenhouse effect …

Catalytic CO x (CO and CO2) hydrogenation to valued chemicals is one of the promising
approaches to address challenges in energy, environment, and climate change. H2O is an …

Inexpensive group VIII metal (ie, Fe, Co, and Ni)-based solid catalysts have been widely
used in various energy transformation processes such as Fischer–Tropsch (F–T) synthesis …

The Fischer–Tropsch product, water, is regularly hypothesized to be the driving force for
catalyst deactivation. Cobalt nanoparticles may be oxidized to CoO, form mixed-metal …