Enhanced Kinetic Removal of Ciprofloxacin Onto Metal-Organic Frameworks by Sonication, Process Optimization and Metal Leaching Study

Overview

Journal Nanomaterials (Basel)

Date 2019 Oct 11

PMID 31597245

Citations 10

Authors

Aliakbar Dehghan

Ali Akbar Mohammadi

Mahmood Yousefi

Ali Asghar Najafpoor

Mahmoud Shams

Shahabaldin Rezania

Affiliations

Soon will be listed here.

Abstract

Metal-organic frameworks (MOFs) are currently recognized as unique platforms for environmental studies. This study evaluated the potential of nine MOFs from ZIF-8, ZIF-67, and UIO-66 families for the removal of ciprofloxacin (CIP), a toxic, bio-accumulative, and persistent fluoroquinolone antibiotic. ZIF-67-SO, with a rhombic crystalline morphology and 1375 m/g BET surface area, has the highest CIP adsorption efficiency among the studied MOFs. The mathematical sorption model predicted that the highest CIP removal (99.2%) occurs when adsorbent dose, pH, and agitation time are adjusted to 6.82, 832.4 mg/L, and 39.95 min, respectively. Further studies revealed that the CIP adsorbed onto ZIF-67-SO in monolayer (q: 2537.5 mg/g) and chemisorption controlled the rate of the process. Mass transfer kinetic coefficients improved significantly by sonication at 35 KHz in comparison with mechanical agitation. Thermodynamic parameters (minus signs of ∆G° [7.8 to 14.2], positive signs of ∆H° (58.9 KJ/mol), and ∆S° (0.23 KJ/mol·K)) demonstrated the spontaneous, endothermic, and chemical sorption of CIP. The level of cobalt leached from ZIF-67-SO structure varied 1.2-4.5 mg/L, depending on pH, mixing time, and agitation type. In conclusion, the excellent adsorption properties of ZIF-67-SO for CIP, made it an outstanding candidate for environmental protection purposes.

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