Selective adsorption of ofloxacin and ciprofloxacin from a binary system using lignin-based adsorbents: Quantitative analysis, adsorption mechanisms, and structure-activity relationship

A series of actinia-shaped lignin-based adsorbents (LNAEs) featuring lignin (LN) as the core and grafted poly (acrylic acid) (PAA) as the tentacle were designed and fabricated. Two fluoroquinolones (FQs) with similar molecular structures, ofloxacin (OFL) and ciprofloxacin (CIP), were used as targets to study the selective adsorption performance of LNAEs associated with the structural effects of the LN-based adsorbents in FQs binary aqueous system. The adsorption of the two FQs by LNAEs complied with the competitive Langmuir isothermal model, and showed selective removal of CIP over OFL due to the additional negative charge-assisted hydrogen bond (CAHB) formed between the carboxyl group of LNAEs and the secondary amino group of CIP, in addition to the effects of electrostatic attraction and normal hydrogen bonds, according to quantitative studies and density functional theory analysis. A binary nonlinear model based on phenomenological theory was applied to study the effects of PAA branched-chain length and distribution on the selective adsorption performance of the LN-based adsorbents. Accordingly, the branched-chain distribution played a more important role and higher distribution density of branched PAA could expose more adsorption sites on LNAEs' surface and improve the adsorptive selectivity. This study offers a well understanding of the structure-activity relationship of the surface grafting modified adsorbents in binary pollutant systems and fundamental guidance for the exploitation and design of novel and efficient adsorbents. (C) 2020 Elsevier B.V. All rights reserved.

Automated summary

A series of actinia-shaped LNAEs were designed with LN as the core and grafted PAA as the tentacle, showing selective removal of CIP over OFL due to the CAHB formed between the carboxyl group of LNAEs and the secondary amino group of CIP, with the distribution of branched PAA playing a key role in improving adsorptive selectivity. This study provides a fundamental understanding of the structure-activity relationship of modified adsorbents and offers guidance for the development of novel and efficient adsorbents in binary pollutant systems.