From normal crosslinking to core–shell structure: Improved performance of β-cyclodextrin based adsorbent toward efficient separation of acetophenone and 1-phenylethanol

To efficiently separate acetophenone (AP) and 1-phenyethanol (PE) from petrochemical by-product, we herein report a novel feasible strategy to fabricate β-cyclodextrin (β-CD) based core–shell microsphere, which retains the cage-type crystal structure of β-CD and superior affinity to AP over PE. Using triphenylmethane-4,4′,4′'-triisocyanate (TTI) as monomer, the polymeric TTI shell can grow in-situ on the surface of β-CD particles, giving the core–shell structured [email protected] The unique β-CD core and polymeric TTI shell structure was verified by a series of characterization methods. [email protected] exhibits both high AP uptake (ca. 2.07 mmol·g−1) and AP/PE selectivity (ca. 7.2), outperforming the conventional TTI cross-linked amorphous β-CD polymer (TTI-CDP). The adsorption behavior of [email protected] on AP and PE single-component solutions was investigated by batch adsorption experiments. Based on the experimental and theoretical results, a mechanism of competitive adsorption of AP and PE on [email protected] involving host–guest inclusion, hydrogen bonding and π-π stacking is proposed. Furthermore, intense competition between AP and PE on [email protected] was observed in column breakthrough experiments, and [email protected] could purify AP from 77.16% to 93.6% by a single adsorption–desorption process.