Ciprofloxacin adsorption on graphene and granular activated carbon: kinetics, isotherms, and effects of solution chemistry

Ciprofloxacin (CIP) is a commonly used antibiotic and widely detected in wastewaters and farmlands nowadays. This study evaluated the efficacy of next-generation adsorbent (graphene) and conventional adsorbent (granular activated carbon, GAC) for CIP removal. Batch experiments and characterization t...

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Bibliographic Details
Published in:Environmental technology 2015-12, Vol.36 (24), p.3094-3102
Main Authors: Zhu, Xuan, Tsang, Daniel C.W, Chen, Feng, Li, Shiyu, Yang, Xin
Format: Article
Language:English
Subjects:
Activated carbon
Adsorbents
Adsorption
adverse effects
Agricultural land
Agricultural wastes
Anti-Bacterial Agents - chemistry
Antibiotics
Charcoal - chemistry
Ciprofloxacin
Ciprofloxacin - chemistry
Drinking water
environmental technology
Fourier transform infrared spectroscopy
Fourier transforms
Graphene
Graphite - chemistry
Ionic strength
Isotherms
Kinetics
Mathematical models
nanomaterials
Organic chemistry
Organic matter
pH effects
Reaction kinetics
river water
Rivers
Solution chemistry
sorption isotherms
Speciation
surface area
Surface chemistry
Thermodynamic equilibrium
Thermodynamic properties
Thermodynamics
Waste Disposal, Fluid - methods
wastewater
Water Pollutants, Chemical - chemistry
water treatment
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Summary:Ciprofloxacin (CIP) is a commonly used antibiotic and widely detected in wastewaters and farmlands nowadays. This study evaluated the efficacy of next-generation adsorbent (graphene) and conventional adsorbent (granular activated carbon, GAC) for CIP removal. Batch experiments and characterization tests were conducted to investigate the adsorption kinetics, equilibrium isotherms, thermodynamic properties, and the influences of solution chemistry (pH, ionic strength, natural organic matter (NOM), and water sources). Compared to GAC, graphene showed significantly faster adsorption and reached equilibrium within 3 min, confirming the rapid access of CIP into the macroporous network of high surface area of graphene as revealed by the Brunner–Emmet–Teller measurements analysis. The kinetics was better described by a pseudo-second-order model, suggesting the importance of the initial CIP concentration related to surface site availability of graphene. The adsorption isotherm on graphene followed Langmuir model with a maximum adsorption capacity of 323 mg/g, which was higher than other reported carbonaceous adsorbents. The CIP adsorption was thermodynamically favourable on graphene and primarily occurred through π − π interaction, according to the FTIR spectroscopy. While the adsorption capacity of graphene decreased with increasing solution pH due to the speciation change of CIP, the adverse effects of ionic strength (0.01–0.5 mol L ⁻¹), presence of NOM (5 mg L ⁻¹), and different water sources (river water or drinking water) were less significant on graphene than GAC. These results indicated that graphene can serve as an alternative adsorbent for CIP removal in commonly encountered field conditions, if proper separation and recovery is available in place.
ISSN:1479-487X
0959-3330
1479-487X
DOI:10.1080/09593330.2015.1054316