Tracking the Molecular-Scale Mechanistic Pathway of Trapping-Bonding CTAB/Fe3O4-AS for High-Performance Cr(VI) Adsorption

•Tracked Cr(VI) reduction and bonding on CTAB/Fe3O4-AS using DFT and MD simulations.•Chitin’s adjacent amide groups govern reduction-coordination in electron transfer.•CTAB/Fe3O4-AS enhances adsorption capacity and selectivity for Cr(VI).•CTAB/Fe3O4-AS can remove over 99% of Cr(VI) from actual elect...

Full description

Saved in:
Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-10, Vol.497, p.155053, Article 155053
Main Authors: Ren, Binqiao, Jin, Yu, Song, Xiaoxiao, Zhao, Luyang, Han, Xue, Zhang, Yuying, Cui, Chongwei, Liu, Rui, Cui, Han
Format: Article
Language:English
Subjects:
Aspergillus niger spores
Biosorption
Cr(VI)
CTAB/Fe3O4-AS
Reduction
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Tracked Cr(VI) reduction and bonding on CTAB/Fe3O4-AS using DFT and MD simulations.•Chitin’s adjacent amide groups govern reduction-coordination in electron transfer.•CTAB/Fe3O4-AS enhances adsorption capacity and selectivity for Cr(VI).•CTAB/Fe3O4-AS can remove over 99% of Cr(VI) from actual electroplating wastewater.•CTAB/Fe3O4-AS can be quickly recovered through magnetic separation. [Display omitted] Cr(VI) contamination threatens the environment and health, necessitating urgent, sustainable removal solutions. Composite biological adsorbents are promising, yet the molecular-level adsorption mechanisms remain unclear. This gap in understanding hinders the development and application of more efficient biological adsorbent materials. Here, we propose a magnetic composite adsorbent based on Aspergillus niger spores (CTAB/Fe3O4-AS) to track the trapping-bonding mechanisms of Cr(VI) on its surface. Characterization analysis showed that Fe3O4 nanoparticles and CTAB form a stable magnetic shell and an outermost quaternary ammonium layer on the spore surface. This synergistic structure enhanced the Cr(VI) adsorption capacity to 186 mg·g−1 at pH 2.0 in solution and achieved a Cr(VI) removal rate exceeding 99 % in electroplating wastewater, with dosage of 1.8 g·L−1 after 180 min. CTAB/Fe3O4-AS selectively removes Cr(VI) from acidic wastewater, with selectivity coefficients of KCr/Zn = 1334 and KCr/Cu = 2661. Cr(VI) removal occurs mainly through chemical adsorption via heterogeneous processes. DFT calculations and MD simulations visualize reaction pathways and interaction strengths at the molecular scale. The quaternary ammonium cation group ((CH3)4-N+) in CTAB traps Cr(VI) ions electrostatically, transferring them to the spore surface. Electron-donating groups (–COO, –NH-) on the spores reduce Cr(VI) to Cr(III). Amide groups in chitin create optimal coordination sites for Cr(III) by twisting, with nitrogen atoms forming stable complexes through coordination bonds with Cr(III)’s vacant orbitals. This study not only developed an efficient microbial-based composite adsorbent but also proposed a novel synergistic adsorption mechanism: electrostatic trapping–reduction–coordination bonding. This provides valuable insights for developing more efficient and applicable heavy metal ion adsorbent materials in the future.
ISSN:1385-8947
DOI:10.1016/j.cej.2024.155053