A hydroxy-containing
covalent organic framework (COF) was successfully
obtained via a simple nitrogen-purge synthetic procedure for the first
time. The COF favored a serrated AA-stacking arrangement, which enhanced
the stability compared with common AA or AB arrangements. To validate
the potential of the COF in environmental applications, we decorated
the COF onto NiFe2O4 and used the NiFe2O4@COF nanocomposite for magnetic solid-phase extraction
of trace bisphenols (BPs). The parameters affecting extraction efficiencies
were systematically optimized. Under the optimum extraction conditions,
calibration plots showed good linearity (5.0–1.0 × 103 ng mL–1) for six BPs, and limits of detection
varied from 0.14 to 0.73 ng mL–1. Molecular polarity
indexes and molecular dynamics simulations revealed why the COF could
efficiently recognize and capture BPs. An adsorption mechanism related
to the interaction between BP clusters and the COF was discovered.
Ecotoxicological assessment of BPs further unraveled the significance
of the developed method for the timely tracking of the concentration,
distribution, and migration of BPs in environmental media.