A switchable-oxidative cellulose filter paper bearing immobilized Mn-(III)-salen complex for alcohol oxidation

Surface modifications of polysaccharide filter papers can alter their catalytic properties significantly. In particular, polysaccharides have gained increasing interest in the development of heterogeneous catalysts. This wok introduces a new approach to the heterogeneous/ sustainable cat-alytic system preparation based on a catalytic filter paper modified by silylation followed by immo-bilization of a Mn(III)-salen complex as a novel catalytic filtration or portable catalysis. Oxidation of alcohols as well as direct conversion of alcohols to Schiff bases and oximes were per-formed by filtration and passing the reactants through the modified filter paper. Oxidation of benzyl alcohol in the presence of molecular oxygen and NaOCl, selectively leads to aldehydes and car-boxylic acids, respectively. The direct conversion of alcohols to Schiff bases and oximes resulted in the formation of insoluble products on the filter paper. Another advantage of the modified filter paper was its stability and reusability for several times with preservation of the catalytic activity and swellability, which no shrinkage during consecutive wetting-drying cycles was observed. Also, a deep study was conducted over mechanism, reusability/stability, and control experiments of the alcohol oxidation. This study gave new insights into the catalytic propensities of a cellulose filter paper via filtration of reactants.(c) 2022 Published by Elsevier B.V. on behalf of King Saud University. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Automated summary

This study introduces a new approach to preparing a catalytic filtration or portable catalytic system based on modified polysaccharide filter paper, demonstrating its ability to oxidize alcohols and convert them directly into Schiff bases and oximes. The modified filter paper shows stability and reusability, with a deep investigation into the mechanism and stability of alcohol oxidation.