Design and Fabrication of Plasmonic Hedgehog-Shaped Covalent Organic Framework Nanocomposites for Indirect SERS-based Ultradetection of Water Contaminant Terbutryn

Abstract

Surface-enhanced Raman scattering (SERS) spectroscopy is an ultrasensitive analytical technique, the efficiency of which can be enhanced by developing plasmonic nanostructured substrates and sieving elements to capture target analytes close to the plasmonic surface. This study reports the development of a plasmonic hedgehog-shaped colloidal covalent organic framework (SiO₂@Au@ COFHedgehog) composite as an efficient SERS substrate. First, hedgehog-shaped COF particles were synthesized, fully characterized, and their development was studied over time to gain insight into their formation. Then, SiO₂@Au@COFHedgehog composite was prepared, retaining the characteristics of the crystalline COF and the hedgehog-type morphology. The composite exhibited significantly enhanced SERS intensity for 4-nitrothiophenol (4-NTP), which has a strong affinity for the Au surface via S-Au bond formation, achieving a limit of detection (LoD) of 10^–10 M. This demonstrated that molecules with high affinity for the Au surface and smaller than the COF pore size (< 3 nm) can diffuse easily through the pore. Furthermore, an indirect SERS strategy for the detection of the toxic herbicide terbutryn was designed based on the reduction of the nitro group in 4-NTP to form 4,4-dimercaptoazobenzene (DMAB) when terbutryn molecules were placed close to 4-NTP-coated AuNPs, thanks to the high adsorption efficiency of the porous anisotropic COF shell by this herbicide (>50%), revealing a strong correlation between the SERS intensity ratios of specific peaks with an impressive LoD of 10^–9 M (220 ng/L). Overall, these findings underscore the potential of plasmonic hedgehog-shaped COF composites as innovative nanomaterials for SERS-based detection, highlighting the exciting possibilities for developing sensitive and selective sensors for various target molecules, with implications in environmental analysis, biomedicine, and fields requiring ultrasensitive analytical techniques