Functionalized iminodiacetic acid pectin/montmorillonite hydrogel for enhanced adsorption of 4-nitrophenol from simulated water: An integrated approach of response surface optimization and non-linear modeling

Abstract

This research focuses on the modification of pectin through an amination reaction, followed by the development of a novel iminodiacetic acid-functionalized pectin/montmorillonite hydrogel nanocomposite (IMAP/MMT) using gamma radiation. This composite was investigated as an adsorbent for 4-nitrophenol removal from aqueous solutions. Central composite design was utilized for numerical optimization, identifying the maximum adsorption capacity under optimal conditions [0.8 g/L; 52 min;4 pH, 73 mg/L). A decrease in Qm (330.19 to 273.96 mg/g) with increasing temperature indicated an exothermic adsorption process, supported by the calculated ΔH° value of −28.39 kJ/mol. Analysis of pH, FTIR, and XPS results revealed that the primary mechanisms for 4-nitrophenol uptake include hydrogen bonding, π-π interactions, and n-π interactions. Additionally, the Temkin and D-R isotherms, along with ΔH° values, confirmed the physical nature of the adsorption process, as evidenced by bT (0.70–0.86 kJ/mol) and E (0.74–0.82 kJ/mol) values. The IMAP/MMT composite exhibited superior adsorption selectivity, efficient performance in real water, and good reusability, with a rate of 79.4 % maintained for up to five cycles, highlighting its potential for practical applications as an effective adsorbent. Overall, the findings suggest that IMAP/MMT can serve as an environmentally and economically sustainable material for the removal of 4-nitrophenol from wastewater.