Transition‐Metal‐Containing Porphyrin Metal–Organic Frameworks as π‐Backbonding Adsorbents for NO₂ Removal Article Swipe

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Adsorption Metal-organic framework Transition metal Materials science Porphyrin Hydrogen bond Porosity Chemical engineering Metal Inorganic chemistry Photochemistry Chemistry Molecule Organic chemistry Catalysis Metallurgy Composite material Engineering

Shanshan Shang , Chao Yang , Chenguang Wang , Jun‐Sheng Qin , Yi Li , Qinfen Gu , Jin Shang ·

YOU? · · 2020 · Open Access · · DOI: https://doi.org/10.1002/anie.202007054 · OA: W3044313330

Mitigating ambient nitrogen dioxide (NO 2 ) pollution via selective adsorption on porous materials is a promising approach to tackle such an increasingly pressing environmental health issue. However, very few porous adsorbents have sufficiently high NO 2 adsorption capacity and good regenerability simultaneously. Here we attempt to address this challenge by developing π‐backbonding adsorbents in the transition metal (TM) incorporated porphyrin metal–organic frameworks (PMOFs). Breakthrough experiments show that PMOFs with inserted TMs achieve appreciable NO 2 capacity and good regenerability. Combined in situ DRIFTS, synchrotron powder XRD, and DFT calculations reveal the adsorption mechanism: NO 2 partially transforms to N 2 O 4 and interacts with transition metal via π‐backbonding and Al‐node via hydrogen bonding. This work affords new insights for designing next‐generation adsorbents for ambient NO 2 removal and presents PMOFs as a platform to tailor π‐backbonding adsorbents.