Calcium‐Based Metal‐Organic Framework: Detection and Idiosyncratic Removal of Copper by Nano‐Particle Deposition

A novel calcium‐based metal‐organic framework (CaMOF@LSB) was designed and synthesized, exhibiting dual functionality for both selective detection and removal of Cu2+ ions from aqueous solutions. The framework‘s stability, including solvent and pH variations, was established with notable thermal resilience. Colorimetric Cu2+ detection (≥5 ppm) with a high capture capacity of 484.2 mg g−1 by CaMOF@LSB places this material among the few that ensure efficient colorimetric detection and high removal capabilities of Cu2+ ions. Batch adsorption experiments revealed pH‐dependent behavior and competitive interactions. Langmuir and pseudo‐second‐order kinetics models aptly described adsorption isotherms and kinetics, respectively. Thermodynamic assessments confirmed spontaneous and endothermic adsorption. Mechanistically, nanoparticle deposition contributes to the Cu2+ uptake. CaMOF@LSB also exhibited one of the best removal behaviour of Cu2+ by means of oxide formation on the surface. Regeneration of CaMOF@LSB was achieved by simple sonication in 0.1 M aqueous NaOH solution. The recyclability was also tested up to 5 cycles, and it exhibited a small decrease in adsorption capacity observed across the cycles. This research presents a promising avenue for addressing heavy metal pollution using metal‐organic frameworks, thereby offering potential applications in water purification and environmental pollution monitoring and remediation. Herein, a cost‐effective, environmentally benign calcium‐MOF has been synthesized by microwave irradiation, having selective and reusable copper detection and removal capability from wastewater. This material, upon interaction with copper solution, undergoes a color change from yellow to reddish with a detection limit of≥5 ppm and has a removal capacity of 484.2±30 mg g−1 that adsorbed copper as copper oxide nanoparticles.