The objective of this study was the synthesis of a novel nanocomposite (CoZnAl‐layered double hydroxide [LDH]/graphene oxide [GO]) to solve the adsorption problem of positively charged pollutants by LDHs. To prepare this nanocomposite, CoZnAl‐LDH and GO were synthesized by coprecipitation and modified Hummers methods, respectively. After ultrasonic pretreatment, they were combined to produce CoZnAl‐LDH/GO nanocomposite with a smooth and uniform texture which used to remove methylene blue as a cationic model pollutant. The synthesized nanocomposite showed a good adsorption capacity with the maximum adsorption capacity of 169.49 mg/g according to the Langmuir model. The effect of temperature on the adsorption process was surveyed by thermodynamic studies confirming the desirability and the spontaneity of the adsorption process. According to kinetic results, the pseudo‐second‐order model fitted the adsorption process, well. Meanwhile, it was determined that the adsorption process, especially in the beginning, had a high rate and 70% of the pollutant was removed within the first 5 min. Also, the effect of pH on the pollutant removal efficiency was investigated. Finally, the reusability of the nanocomposite was tested. High adsorption capacity and rate, the wide range of operational pH (4–10), and good reusability all suggest that CoZnAl‐LDH/GO is a promising adsorbent for industrial and practical uses.
CoZnAl-layered double hydroxide (LDH) was synthesized by homogeneous co-precipitation. CoZnAl-Mixed Metal Oxide (MMO) was prepared by calcining the LDH. The samples' structure and morphology were studied by analytical techniques including X-ray diffraction, N2 adsorption-desorption isotherm, scanning electron microscopy and UV–visible spectroscopy. Acid orange 7 (AO7) adsorption by as-prepared samples was studied. CoZnAl-MMO showed 526.32 mg/g adsorption capacity, higher than that of CoZnAl-LDH, 243.9 mg/g. Kinetic studies confirmed the pseudo-second-order and pseudo-first-order AO7 adsorption kinetics of the LDH and MMO, respectively. AO7 adsorption onto both LDH and MMO fitted the Langmuir isotherm model well. Band gap calculation confirmed the ability of this nano-MMO to operate in the visible light region. It displayed synergetic adsorption-photocatalytic performance under visible-light and the removal efficiency was about 97%.
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