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Abstract The escalating presence of per‐ and polyfluoroalkyl substances (PFAS) in drinking water poses urgent public health concerns, necessitating effective removal. This study presents a groundbreaking approach, using viologen to synthesize covalent organic framework nanospheres: MELEM‐COF and MEL‐COF. Characterized by highly crystalline features, these nanospheres exhibit exceptional affinity for diverse anionic PFAS compounds, achieving simultaneous removal of multiple contaminants within 30 min. Investigating six anionic PFAS compounds, MEL‐ and MELEM‐COFs achieved 90.0–99.0% removal efficiency. The integrated analysis unveils the synergistic contributions of COF morphology and functional properties to PFAS adsorption. Notably, MELEM‐COF, with cationic surfaces, exploits electrostatic and dipole interactions, with a 2500 mg g⁻¹adsorption capacity—surpassing all reported COFs to date. MELEM‐COF exhibits rapid exchange kinetics, reaching equilibrium within 30 min. These findings deepen the understanding of COF materials and promise avenues for refining COF‐based adsorption strategies. 

Abstract The first synthesis and comprehensive characterization of two vinyl tetrazine‐linked covalent organic frameworks (COF), TA‐COF‐1 and TA‐COF‐2, are reported. These materials exhibit high crystallinity and high specific surface areas of 1323 and 1114 m²g⁻¹. The COFs demonstrate favorable band positions and narrow band gaps suitable for light‐driven applications. These advantages enable TA‐COFs to act as reusable metal‐free photocatalysts in the arylboronic acids oxidation and light‐induced coupling of benzylamines. In addition, these TA‐COFs show acid sensing capabilities, exhibiting visible and reversible color changes upon exposure to HCl solution, HCl vapor, and NH₃vapor. Further, the TA‐COFs outperform a wide range of previously reported COF photocathodes. The tetrazine linker in the COF skeleton represents a significant advancement in the field of COF synthesis, enhancing the separation efficiency of charge carriers during the photoreaction and contributing to their photocathodic properties. TA‐COFs can also degrade 5‐nitro‐1,2,4‐triazol‐3‐one (NTO), an insensitive explosive present in industrial wastewater, in 20 min in a sunlight‐driven photocatalytic process; thus, revealing dual functionality of the protonated TA‐COFs as both photodegradation and Brønsted acid catalysts. This pioneering work opens new avenues for harnessing the potential of the tetrazine linker in COF‐based materials, facilitating advances in catalysis, sensing, and other related fields. 

Abstract The synthesis of a fluorescent covalent organic framework (COF) using perylene and pyrene building blocks (PEPy‐COF), via a one‐pot condensation reaction is reported. PEPy‐COF is crystallized into 2D nanosheets with a cubic and prismatic crystalline morphology and demonstrates structural stability at temperatures up to 500 °C. The structural morphology is confirmed using X‐ray diffraction and atomic‐level simulations. These 2D porous polymer sheets form a tetragonal framework that is found to have a high specific surface area of 772 m²g⁻¹. Based on the definition of porous materials, the network is mesoporous with an observed pore size of 3.03 nm, which is in good agreement with the material's calculated pore size. The experimentally obtained HOMO‐LUMO band gap is 2.62 eV, confirming the semiconducting nature of PEPy‐COF. PEPy‐COF emits a shiny blue luminescence under UV and visible light. This luminescence intensity is temperature‐dependent in solvents with different polarities and dielectric constants demonstrating that the PEPy‐COF has potential use in a wide range of temperature‐sensing devices. The fluorescence intensity ratio is similar for different temperatures under ultra‐sound conditions and varying solvents.