Removal of linear siloxanes and dimethyl sulfone from water using hierarchical zeolite porous carbon adsorbents

• Published in: Journal of hazardous materials Vol. 440; p. 129805
• Main Authors: Vega-Santander, Dariana R., Muñoz-Senmache, Juan C., Borrero-Negrón, Justin, Pagán-Torres, Yomaira J., Hernández-Maldonado, Arturo J.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.10.2022
• Subjects: Dimethyl sulfone; Hierarchical composite; in-situ growth; Linear siloxanes; Silver complexation; Water remediation; Zeolite; Silver complexation; Linear siloxanes; Water remediation; in-situ growth; Hierarchical composite; Zeolite; Dimethyl sulfone
• ISSN: 0304-3894; 1873-3336
• DOI: 10.1016/j.jhazmat.2022.129805

Low molecular weight linear siloxanes are problematic compounds known to occur in water bodies, especially in water reclaimed from closed volumes. Remediation was attempted using a hierarchical porous composite adsorbent containing a Faujasite zeolite imprinted in activated carbon, namely CFAU. Although CFAU was prepared using procedures reported elsewhere, it was modified also to include extra-framework Ag+ cations. The composites long-range, textural, and compositional characteristics were verified via XRD, nitrogen porosimetry, water contact angle, zeta potential, TGA, and ICP elemental analyses. Furthermore, the composites were tested for the adsorption of siloxanes (i.e., monomethylsilanetriol, dimethylsilanediol, and trimethylsilanol (TMS)) as well as dimethyl sulfone (DMSO2) from water (mg L−1 level) in single and multicomponent fashion at ambient temperature and neutral pH. DMSO2 is highly ubiquitous in reclaimed waters where these siloxanes occur. Ag+-CFAU was the superior adsorbent, with siloxane and DMSO2 loadings of up to 20 and 87 mg cm−3 (or 17 and 72 mg g−1), respectively. These are at least an order of magnitude larger than commercial alternatives like carbon and resins. FTIR data suggest that the adsorption interaction with siloxanes is of Van der Waals type, whereas interactions between Ag+-CFAU and DMSO2 plausibly involve complexation. Moreover, multicomponent adsorption tests showed that Ag+-CFAU excels probably because of the complexation with DMSO2 and a TMS-driven siloxane co-adsorption. [Display omitted] •Zeolite-carbon composite adsorbent for water ultra-purification.•Zeolite crystal growth via confined space synthesis.•Selectivity toward low molecular weight siloxanes.•Selectivity toward dimethyl sulfone via complexation with Ag+.•Siloxanes co-adsorption driven by trimethylsilanol.