Valorization of waste oyster shells via thermal and acid activation for Congo red dye adsorption from aqueous media.
Huynh Nhi Le, Hoai Phuong Nguyen Thi, Phuong Anh Cao, Ba Cuong Nguyen, Van Bang Nguyen, Duong Duc La
Abstract
Open AccessA scalable route to valorize waste oyster shells into an effective adsorbent for Congo red removal is reported. Sequential thermal calcination (500 °C) and H3PO4 activation convert the CaCO3 matrix into Ca-phosphate-rich surfaces (XRD, FTIR) bearing abundant -OH/PO4 groups. Despite a moderate BET area (MOS: 22.15 m2 g-1), the modified oyster shell achieves rapid uptake (>80-90% removal within 10 min; near-complete by 60 min), broad pH tolerance with optimal performance below pHpzc ≈ 8.06, and high capacity (q max = 50.89 mg g-1). Kinetics follow a pseudo-second-order model (R 2 = 0.994; k 2 = 0.0127 g mg-1 min-1) and equilibrium data fit both Freundlich (R 2 = 0.997; K F = 37.19; n = 2.97) and Langmuir (K L = 4.21 L mg-1) models, indicating chemisorptive affinity on an energetically heterogeneous surface. MOS is durable and regenerable (∼95% removal after five cycles). Density functional theory calculations corroborate strong dye-phosphate site interactions. The combined thermal-acid treatment thus yields a low-cost, reusable adsorbent suitable for practical dye-laden wastewater treatment.