Green approach for the synthesis of a acrylonitrile hyperbranched polymer/chitosan composite for the removal of diclofenac from water: determination of optimal conditions using statistical experiment design†
Atif Afroz, Mohd Nasir, Mohammad Kashif and Mohammad Shahzad Samdani
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Abstract
Acrylonitrile hyperbranched polymer/chitosan composite (AC–Hyp/CS) material was synthesized for the removal of diclofenac. In this method, a hyperbranched polymer was prepared by crosslinking an acrylonitrile monomer to obtain a host with a large surface area (AC/Hyp). To improve the functional sites of AC/Hyp, it was functionalized with chitosan (AC–Hyp/CS), which led to excellent removal efficiency. The physiochemical characterization of AC–Hyp/CS was carried out using FTIR, XPS, PXRD, DLS, TGA-DTA and SEM coupled with EDS. The uptake of diclofenac by AC–Hyp/CS was optimized through RSM in combination with BBD. Four factors, namely, AC–Hyp/CS dose (0.002–0.0180 g), concentration of diclofenac (10–30 mg L−1), solution pH (2–6) and contact time (20–100 min), were considered to examine influencing parameters that resulted in the excellent removal efficiency. A high value of R2 (0.9969) confirmed the excellent agreement of equilibrium data to the quadratic model. The obtained results suggested that 0.01 g AC–Hyp/CS was sufficient to eliminate 99.6% diclofenac from 20.0 mL (20.0 mg L−1) solution at pH 4. Isothermal investigation suggested that the Langmuir isotherm model was administrated well with equilibrated data as it showed appropriate R2 values (0.9814–0.9908) and low values of error functions (SSE: 0.002–11.742, χ2: 1 × 10−5–0.048 and RMSD: 0.0447–3.426). The adsorption capacity (maximum) obtained from the Langmuir model was 200 mg g−1. The high values of R2 (0.9878–0.9982) and low values of error functions (SSE: 0.160–1.343, χ2: 0.004–0.0534, RMSD: 0.40–1.158) of the pseudo-second-order kinetic model confirmed that the absorption was chemisorption. Diffusion-based kinetic studies revealed that both diffusion processes (film and intraparticle) participated in this sorption. Adsorption/desorption cycling test suggested that the composite exhibited excellent reusability characteristics up to 7 cycles, which confirmed that AC–Hyp/CS could be an effective sorbent for elimination of diclofenac from aqueous environments.
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