Highly Mesoporous Hybrid Transition Metal Oxide Nanowires for Enhanced Adsorption of Rare Earth Elements from Wastewater

Removal of rare earth elements (REEs) from industrial wastewater is a continual challenge. To date, several approaches to the synthesis of nanoadsorbant for this application have been reported, although these are characterized by insufficient adsorption capacity and limitations in cycling stability. The present worl reports the fabrication and performance of hierarchical hybrid transition metal oxide (TMO) nanowires deposited on carbon fibers. An ordered assembly of hybrid TMC) nanowires exhibits an outstanding adsorbance of 1000 mg.g(-1) of REEs with 93% recyclability. This superior performance is attributed to the unique mesoporous architecture of the nanowires, which exhibits a high surface area of 122 cm(3).g(-1). Further, rapid adsorption/desorption of the REEs reveals minimal morphological alteration and hence high structural stability of these hybrid TMO nanowires aftei multiple cycles. The ready accessibility of the adsorption sites at crystallite boundaries and the surfaces as well as rapid adsorption of the REEs on the mesoporous nanostructure facilitate considerable adsorption capacity, improved structural stability, and extended cyclability, all of which suggest the potential for this material in REE extraction.

Automated summary

This study reports the fabrication and performance of hierarchical hybrid transition metal oxide nanowires deposited on carbon fibers, which exhibit outstanding adsorption capacity and cycling stability for rare earth elements. The unique mesoporous architecture of the nanowires allows for high surface area and rapid adsorption/desorption of REEs, suggesting great potential for REE extraction.