AI Article Synopsis
- Enhancing water pollution remediation involves improving the synergy between adsorption and catalytic oxidation, posing a significant challenge in the field.
- This study introduces new carriers made of silica and hydroxyapatite, integrated with various forms of copper species for creating effective Fenton-like catalysts with strong stability and recyclability.
- The catalysts demonstrate superior dye degradation performance, leveraging their unique ability to collaborate between adsorption sites and catalytic centers, which is further explained by the identification of reactive oxygen species and electrochemical testing.
Article Abstract
Enhancing the synergistic interplay between adsorption and catalytic oxidation to amplify Fenton-like effects remains a pivotal challenge in advancing water pollution remediation strategies. In this study, a suite of novel carriers (SH) composed of silica (SiO) and hydroxyapatite (HAp) in different ratios were synthesized through an amalgamation of the sol-gel and co-precipitation techniques. Notably, various forms of copper (Cu) species, including Cu ions and Cu nanoclusters (Cu NCs), could be stably incorporated onto the SH surface via meticulous loading and doping techniques. This approach has engendered a new class of Fenton-like catalysts (Cu NCs-SH1-5) characterized by robust acid-base tolerance stability and remarkable recyclability. Compared with the previously reported Cu NCs-HAp, this catalyst with lower Cu species content could achieve better performance in adsorbing and degrading dyes under the aid of hydrogen peroxide (HO). The catalyst's dual action sites, specifically the adsorption sites (SiOH, POH, slit pores) and catalytic centers (multivalent Cu species), had clear division of labor and collaborate with each other. Further, reactive oxygen species (ROS) identification and astute electrochemical testing have unveiled the mechanism underpinning the cooperative degradation of dyes by three types of ROS, spawned through electron transfer between the Fenton-like catalyst (Cu NCs-SH) and HO. From these insights, the mechanism of synergistic adsorption-catalytic removal was proposed.
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| http://dx.doi.org/10.1016/j.jcis.2024.04.120 | DOI Listing |
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Article Synopsis
- Enhancing water pollution remediation involves improving the synergy between adsorption and catalytic oxidation, posing a significant challenge in the field.
- This study introduces new carriers made of silica and hydroxyapatite, integrated with various forms of copper species for creating effective Fenton-like catalysts with strong stability and recyclability.
- The catalysts demonstrate superior dye degradation performance, leveraging their unique ability to collaborate between adsorption sites and catalytic centers, which is further explained by the identification of reactive oxygen species and electrochemical testing.
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