Facile synthesis of zeolite-based MOF composites for cobalt ion separation from simulated wastewater

Background

With the acceleration of industrialization, heavy metal pollution has attracted worldwide attention. As an important heavy metal, cobalt is widely used in fields such as batteries, alloys, and catalysts. However, due to environmental issues and the toxicity of heavy metals, it is crucial to separate cobalt ions from wastewater.

Methods

Zeolitic (Ze) MOF architectures were fabricated through solvent-mediated coordination with aluminosilicate substrates, demonstrating enhanced cobalt(II) sequestration efficacy in synthetic wastewater remediation. Ze serves as a stable, low-cost molecular sieve, providing structural support and Al³⁺ ions for MOF formation. The composites, including Ze-MOFs(Al), Ze-MOFs(Al)-NH₂, and Ze-MOFs(Al)-(OH)₂, were characterized using XRD, FT-IR, SEM, and BET analysis. Their adsorption performance was evaluated under varying conditions, with the adsorption mechanisms explored in detail.

Significant findings

Ze-MOFs(Al) exhibited the highest adsorption capacity (228.3 mg/g) and selective adsorption ability in mixed solutions of Co(II), Li(I), K(I), Mg(II), and Ca(II), underscoring its potential for wastewater treatment. Research on fixed-bed dynamic adsorption revealed adherence to the Thomas model, showing a dynamic adsorption capacity (208.7 mg/g) nearly equivalent to the theoretical static capacity, suggesting a diffusion-driven process. This research provides valuable insights into the development of low-cost, efficient materials for cobalt ion separation from wastewater.