New insight into multi-functional MOG@COP/SA beads for co-adsorption and mono-detection in CTC-Cr(Ⅵ) co-contamination system and efficient anti-counterfeiting

Abstract

Co-contamination of antibiotics and heavy metals in water environment has provoked considerable toxicological concerns. Meantime, residue detection of heavy metals as well as national anti-counterfeiting safety also have driven attempts in wastewater treatment. In this paper, a core–shell hybrid MOG@COP is designed with behaviors superior to pristine components by combining a Zr-based metal–organic gel and a guanidine-based covalent organic polymer, for co-adsorption and mono-detection in chlortetracycline hydrochloride (CTC)-Cr(Ⅵ) co-contamination system and efficient anti-counterfeiting. In single/binary system, the adsorption capacities of CTC and Cr(Ⅵ) behave as 133.69 and 63.45 mg·g−1/181.82 and 64.47 mg·g−1, and the high sensitivity and low detection limit of Cr(Ⅵ) render as 1.46*105 M−1 and 0.20 μM/1.49*102 M−1 and 0.63 mM, respectively. In addition, to solve the powder shortcomings of easy agglomeration and difficult recycling, MOG@COP is fixed into sodium alginate (SA) matrix to fabricate MOG@COP/SA beads, yielding reinforced adsorption performance of CTC/Cr(Ⅵ) in both single system (152.91/92.25 mg·g−1) and binary system (174.83/75.30 mg·g−1). More importantly, a self-constructed adsorption-detection-anti-counterfeiting (ADA) platform is ingeniously developed with the MOG@COP/SA beads as the backfills for continuously processing CTC-Cr(Ⅵ) co-contaminated water, realizing real-time visualization of Cr(Ⅵ) adsorption process and optical anti-counterfeiting protection. In conclusion, this work is expected to not only trigger the reasonable design of the core–shell hybrid MOG@COP/SA beads with versatile performances of simultaneous luminescence monitor, capture and anti-counterfeiting, but also allow the original exploration for all-in-one platform.