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Design of a robust and strong-acid MOF platform for selective ammonium recovery and proton conductivity.

Genki HatakeyamaHongyao ZhouTakashi KikuchiMasaki NishioKouki OkaMasaaki SadakiyoYusuke NishiyamaTeppei Yamada
Published in: Chemical science (2023)
Metal-organic frameworks (MOFs) are potential candidates for the platform of the solid acid; however, no MOF has been reported that has both aqueous ammonium stability and a strong acid site. This manuscript reports a highly stable MOF with a cation exchange site synthesized by the reaction between zirconium and mellitic acid under a high concentration of ammonium cations (NH 4 + ). Single-crystal XRD analysis of the MOF revealed the presence of four free carboxyl groups of the mellitic acid ligand, and the high first association constant (p K a1 ) of one of the carboxyl groups acts as a monovalent ion-exchanging site. NH 4 + in the MOF can be reversibly exchanged with proton (H + ), sodium (Na + ), and potassium (K + ) cations in an aqueous solution. Moreover, the uniform nanospace of the MOF provides the acid site for selective NH 4 + recovery from the aqueous mixture of NH 4 + and Na + , which could solve the global nitrogen cycle problem. The solid acid nature of the MOF also results in the proton conductivity reaching 1.34 × 10 -3 S cm -1 at 55 °C by ion exchange from NH 4 + to H + .
Keyphrases
  • metal organic framework
  • ionic liquid
  • room temperature
  • high throughput
  • risk assessment
  • aqueous solution