Abstract
Chloramphenicol (CAP) is commonly employed in veterinary clinics, but illegal and uncontrollable consumption can result in its potential contamination in environmental soil, and aquatic matrix, and thereby, regenerating microbial resistance, and antibiotic-resistant genes. Adsorption by efficient, and recyclable adsorbents such as mesoporous carbons (MPCs) is commonly regarded as a “green and sustainable” approach. Herein, the MPCs were facilely synthesized via the pyrolysis of the metal–organic framework Fe3O(BDC)3 with calcination temperatures (x °C) between 600 and 900 °C under nitrogen atmosphere. The characterization results pointed out mesoporous carbon matrix (MPC700) coating zero-valent iron particles with high surface area (~225 m2/g). Also, significant investigations including fabrication condition, CAP concentration, effect of pH, dosage, and ionic strength on the absorptive removal of CAP were systematically studied. The optimal conditions consisted of pH = 6, concentration 10 mg/L and dose 0.5 g/L for the highest chloramphenicol removal efficiency at nearly 100% after 4 h. Furthermore, the nonlinear kinetic and isotherm adsorption studies revealed the monolayer adsorption behavior of CAP onto MPC700 and Fe3O(BDC)3 materials via chemisorption, while the thermodynamic studies implied that the adsorption of CAP was a spontaneous process. Finally, adsorption mechanism including H-bonding, electrostatic attraction, π–π interaction, and metal–bridging interaction was proposed to elucidate how chloramphenicol molecules were adsorbed on the surface of materials. With excellent maximum adsorption capacity (96.3 mg/g), high stability, and good recyclability (4 cycles), the MPC700 nanocomposite could be utilized as a promising alternative for decontamination of chloramphenicol antibiotic from wastewater.
Highlights
The arrangement of relative adsorption capacity of materials in this study complied with the order: Fe3 O(BDC)3 < MPC600 < MPC900 < MPC800 < MPC700. These results proposed that MPC700 could be a delegate of the mesoporous carbons (MPCs) family for comparing their remediation efficiency of2019, the selected pharmaceutical CAP with pristine Fe3 O(BDC)3 in the following experiments
The Fe3 O(BDC)3 and MPC700 materials were successfully synthesized via the solvothermal method
The materials were characterized by XRD, FT-IR, scanning electron microscope (SEM), transmission electron microscopy (TEM), BET and VSM
Summary
Tunable transformation of Fe-based MOFs into magnetically and hierarchically mesoporous MPCs has recently reported [22,23,24,25] Direct conversion of these MOFs can be followed by heat treatment, which pore sizes, morphologies, compositions, and properties of MPCs are partially inherited from MOF precursors, and dependent on temperature control [26]. The Fe3 O(BDC) was synthesized from an iron source and carboxylate via the solvothermal method, a facile pyrolysis allowed to directly transform the Fe3 O(BDC) into MPCs. The effect of calcination temperatures on CAP adsorption capacity was investigated to choose the best appropriate material. The as-synthesized black solid was stored in a desiccator
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