Counterions Determine if Metal‐Organic Cages Convert SO2 to Sulfate or Reversibly Adsorb It

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AbstractThe continuous emission of harmful gases into the atmosphere damages the environment, air quality, and public health worldwide. To mitigate their impact, materials that capture and chemically inactivate gases are required; however, integrating and precisely controlling both abilities within a single material remains challenging. Herein, we demonstrate for the first time that switching between SO2‐physisorption and chemisorption is possible for porous materials by using different counterions, as illustrated with a series of Pd6L8 Metal‐Organic Cages (MOCs). Pd‐MOCs bearing BF4−, PF6−, or SO42− expressed reversible adsorption (up to 3.6 mmol g−1), cyclability, and SO2/CO2 selectivity. NO3− promoted conversion of SO2 to sulfate, as corroborated with M6L8 cages built on Co(II), Cu(II), and Zn(II) ions. Noteworthy, the nitrate derivative of Pd6L8 captures 6.0 mmol g−1 of SO2, cleanly transforms it to SO42− within its cavity in 94 % yield at room temperature, it is quantitatively regenerated, and tolerates humid SO2; such qualities are unprecedented for SO2 adsorbents. The deliberate use of counterions for modulating adsorption could be applied to charged MOFs, COFs, or POCs, potentially leading to the development of new reactivity or catalysis pathways for advanced applications against contaminant gases.