Synthesis of high-surface-area mesoporous SnO2 nanomaterials using carbon template

Abstract

Metal oxide porous nanomaterials are of great interest across scientific fields due to their intriguing properties, allowing their usage from lab-scale research to industrial applications. However, the production of high surface area metal oxide nanomaterials still poses significant challenges. This study introduces a novel method for synthesizing highly porous tin oxide (SnO2) nanostructures using carbon as the template material. The synthesis process includes the formation of a precursor composite containing resorcinol-formaldehyde gel and a tin oxide precursor, which is first carbonized to convert the resorcinol-formaldehyde into a porous three-dimensional carbon framework. This framework acts as a scaffold for the nucleation of SnO2 nanoparticles. Subsequent oxidation selectively removes the carbon template, yielding highly porous SnO2 nanomaterials. Electron microscopy analysis shows that the nanomaterials feature a particle size with average diameter of ∼30 nm, whereas Gas adsorption-desorption characterization indicates pronounced mesoporosity, with a pore size of 3 nm and a specific surface area of 476 m2/g. The enhanced surface area surpasses the previously reported studies on porous SnO2. This is significant considering the easy production process of the nanomaterials, which signifies its potential for large-scale production. Furthermore, this approach offers versatility, as different materials can replace the carbon component, allowing for tailored nanostructure design and enhanced properties. The resulting materials can offer exciting possibilities in the field of materials science and nanotechnology.