Characterization and adsorption performance of waste-based porous open-cell geopolymer with one-pot preparation

Porous geopolymer foams are promising lightweight materials combining strong strength and adsorption properties. A waste-based porous open-cell geopolymer (POG) was synthesized by one-pot method and investigated in terms of unconfined compressive strength (UCS), pore distribution and adsorption ability. This paper investigates the effect of preparation conditions (raw materials and stabilizing/foaming agents proportion, modulus, curing temperature) on the performance of POG. Results indicated that POG was successfully prepared by industrial wastes (blast furnace slag, BFS) and municipal wastes (water treatment residue, WTR). The appropriate range of conditions were determined for the preparation of POG (H2O2 = 1.50 - 2.50 wt%, K12 = 1.50 - 2.00 wt%, modulus = 1.25 - 2.00, and temperature = 60 - 70 ?C). Under these conditions, the UCS in the range 1.77 - 4.77 MPa, and the total porosity in the range 35.19 - 69.97 vol%. The extreme environments resulted in the form of instable structure and discontinuous pore structure. The statistical results demonstrated that the total porosity, mean diameter, and max diameter of POG are significantly negative correlated with UCS, and the relationship of total porosity and UCS can be described by Ryshkevith (R2=0.8459) and Schiller model (R2=0.8689). Compared to the geopolymer bulk, POG showed significant adsorption advantage for heavy metal cations and cationic dyes, and the adsorption removal rates of POG for Cd2+, Cu2+, Pb2+, and MB rising to 92.25%, 119.80%, 110.77%, and 163.98%, respectively. The adsorption mechanisms are mainly based on the negative charge of [AlO4]- tetrahedron and cation exchange between heavy cations and Na+ or Ca2+ in internal matrix. This study indicated that the BFS and WTR are feasible solid wastes for the fabrication of POG, which can be applied in the filtration and adsorption fields for contaminants removal.

Automated summary

Porous open-cell geopolymer (POG) was successfully prepared by industrial and municipal wastes, with appropriate conditions determined for its preparation. The study revealed a significant negative correlation between total porosity and UCS, with POG showing great adsorption capabilities for heavy metal cations and cationic dyes. The adsorption mechanism is mainly based on cation exchange between heavy cations and Na+ or Ca2+ in the internal matrix.