Congo Red–Functionalized Maize Stalk for Fe3+, Cr3+ and Mn2+ Adsorption: Multi-Analytical Characterization of Interaction Mechanisms
Nicoleta Mirela Marin, Toma Galaon, Adriana Mariana Borș, Roxana Doina Trusca, Ludmila Motelica, Ovidiu OpreaThis study examines the adsorption and interaction mechanisms of Congo red (CR) immobilized onto maize stalk (MS) to form MS-CR material, used for the removal of Fe3+, Cr3+, and Mn2+ (Mn+) from aqueous media. Initially, the MS was functionalized with CR, achieving adsorption capacities between 41.4 and 48.0 mg/g across pH 2–10, confirming the formation of hydrogen bonding and aromatic interactions, as indicated by the shift of the OH band from 3338.91 to 3335.54 cm−1 and the appearance of characteristic azo–aromatic peaks (1601–1506 cm−1) in the FTIR spectra. Stability tests showed that CR remains anchored to the lignocellulosic matrix even under 2 M HCl/NaOH. Subsequently, adsorption experiments revealed a strong pH dependence: at pH 10, removal efficiencies reached 93% for Mn2+, 89% for Fe3+, and 72% for Cr3+ at 2 mg/L, driven by surface deprotonation and enhanced electrostatic attraction. Increasing the initial metal concentration (1–10 mg/L) led to maximum adsorption capacities of 2.00 mg/g for Fe3+, 1.64 mg/g for Cr3+, and 1.46 mg/g for Mn2+. Desorption experiments identified 0.5 M HCl as the optimal regenerating agent, achieving 90–97% metal release. FTIR analysis of MS-CR–Mn2+ showed the disappearance of the 1243 cm−1 carboxyl band and the emergence of a metal–oxygen vibration at 559.37 cm−1, confirming adsorption via coordination to deprotonated carboxyl and phenolic groups. TG/DSC/DTG analysis demonstrated improved stability of MS-CR compared to native MS. SEM/EDX confirmed the presence of S, Na, and Mn+. The combined spectroscopic, microscopic, and thermal evidence demonstrates that MS-CR operates as a robust, multifunctional adsorbent capable of Mn+ retention, offering a sustainable solution for water treatment.