This article explores the phenomena of catalyst poisoning, regeneration, and reactivation, with particular emphasis on contemporary strategies designed to prolong catalyst lifetime and improve their operational performance in industrial processes. Catalysts gradually experience a decline in their inherent activity as a result of exposure to toxic substances, which consequently diminishes the overall efficiency of chemical reactions and industrial operations. Within this study, the mechanisms of catalyst poisoning—especially those arising from contaminants such as sulfur- and carbon-containing species—are analyzed in detail, and the currently available techniques for removing these detrimental compounds in order to restore catalytic functionality are systematically reviewed. A range of physical and chemical regeneration methods are examined as principal approaches for catalyst recovery, including procedures such as washing, calcination, and reduction treatments employing reducing gases. Furthermore, emerging and advanced strategies for catalyst reactivation are considered, particularly those involving modifications of the catalyst surface structure as well as the utilization of nanotechnology-driven techniques. The central aim of this work is to identify and present effective solutions that enhance catalyst durability and stability while simultaneously minimizing the economic costs associated with catalyst replacement or disposal. By doing so, the study ultimately contributes to improving industrial process efficiency and mitigating adverse environmental impacts.
Forogh et al. (Wed,) studied this question.
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