Influence of calcination atmospheres on the physicochemical properties and catalytic activity of Ni₁Co₁O_x catalyst for CO oxidation

Abstract: Nano‐Ni1Co1Ox spinel catalysts were prepared via a coprecipitation method, followed by calcination in different atmospheres (air, CO air, N2, and static air flow) tested CO oxidation in air. The calcination of basic cobalt‐nickel precursor in CO air mixture flow (4.5 vol.%) led to the formation of nano‐Ni1Co1Ox spinel with highest specific surface area, smallest crystallite size, porous, and well‐dispersed oxygen deficient structural defect morphology as revealed by N2 physiosorption, X‐ray diffraction (XRD), … Show more

“…Neha et al. provided a critical review of current catalytic soot oxidation scenarios, highlights factors affecting catalyst activity, examines kinetic models, and emphasizes recent advancements in stable catalyst design for practical applications in soot oxidation [12] . Till now, rare earth oxide‐based catalysts for efficient soot combustion are rarely summarized in a systematic way.…”

Research Advances in Rare Earth Oxide‐Based Catalysts for Soot Combustion

“…Neha et al. provided a critical review of current catalytic soot oxidation scenarios, highlights factors affecting catalyst activity, examines kinetic models, and emphasizes recent advancements in stable catalyst design for practical applications in soot oxidation [12] . Till now, rare earth oxide‐based catalysts for efficient soot combustion are rarely summarized in a systematic way.…”

Research Advances in Rare Earth Oxide‐Based Catalysts for Soot Combustion

Insights into the interface of NiCo2O4 spinel /LaCoO3 perovskite nano-composite for CO and soot oxidation

Effect of annealing conditions on the physicochemical and photocatalytic properties of a nanopowder based on Fe2TiO5