AI Article Synopsis
- Salicylic acid (SA) was utilized to promote the formation of wormlike micelle aggregates from octadecyl trimethyl ammonium chloride (OTAC), which served as a template for creating a hierarchical MgAl hydrotalcite (LDH) material with a complex pore structure.
- The hierarchical MgAl-LDH was characterized by a dense layered surface, significantly higher specific surface area (113.94 m/g), and a broad pore size distribution (2 to 80 nm), leading to an impressive maximum adsorption capacity of 192.7 mg/g for sulfonated lignite (SL) at pH 7.
- After two regeneration cycles, the MgAl-LDH maintained a high adsorption capacity of 179.1 mg
Article Abstract
In this work, salicylic acid (SA) was used to induce the self-assembly of octadecyl trimethyl ammonium chloride (OTAC), a cationic surfactant, into three-dimensional wormlike micelle aggregates. These aggregates act as a soft template for hierarchical MgAl hydrotalcite (LDH) to create a multi-level pore structure adsorption material. Scanning electron microscopy characterization showed that the surface of the hierarchical hydrotalcite exhibited a dense layered structure, unlike the monolayer structure of ordinary hydrotalcite. Furthermore, the hierarchical MgAl-LDH possesses a significantly larger specific surface area (113.94 m/g) and wide pore size distribution ranging more extensively from 2 to 80 nm, which significantly has an impressive adsorption effect on sulfonated lignite (SL), with a maximum adsorption capacity of 192.7 mg/g at pH = 7. Extensive research has been conducted on the adsorption mechanism of hierarchical MgAl-LDH, attributing it to surface adsorption due to the unique multi-level structure of the adsorbent. After two cycles of regeneration experiments, the adsorption capacity of the adsorbent remained at a high level of 179.1 mg/g, demonstrating the excellent renewability of hierarchical MgAl-LDH. Moreover, the hierarchical hydrotalcite showed high adsorption capacity in the adsorption of sulfonated lignite, which was attributed to its larger specific surface area and superior pore structure to expose more active sites.
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