<p>Controlling local chemical environments within porous crystalline materials is essential for selective adsorption and catalysis, yet remains difficult in stable frameworks with precisely oriented functional sites. Here we use reticular chemistry to programme tunable confinement in triazolate metal–organic frameworks constructed from Kuratowski-type Zn<sub>5</sub>Cl<sub>4</sub> nodes. Linker geometry directs the formation of the ith-d topology, in which terminal Zn-bound groups point inwards to generate confined and chemically addressable pores. This strategy yields two isoreticular frameworks, NU-6000 and NU-6001, with distinct cage dimensions and apertures, while preserving the same topology. Post-synthetic chloride-to-hydroxide exchange installs dense arrays of inward-facing Zn–OH groups without loss of crystallinity, enabling reversible CO<sub>2</sub> chemisorption through bicarbonate formation. Single-crystal analysis of a CO<sub>2</sub> adduct reveals that confinement imposes a geometric accessibility limit on reactive hydroxyl sites within the smallest cage of NU-6000. Under this confinement regime, NU-6000 exhibits strong low-pressure CO<sub>2</sub> capture, including at 30 ppm, and achieves 61.4% site utilization at 420 ppm, among the highest reported for metal–organic frameworks under comparable conditions.</p>

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Programming local confinements in crystalline frameworks through reticular chemistry

  • Xianhui Tang,
  • Xiaoliang Wang,
  • Zi-Ming Ye,
  • Shengyi Su,
  • Julian S. Magdalenski,
  • Bang Hou,
  • Timothy Y.-Z. Li,
  • Kent O. Kirlikovali,
  • Nathan C. Gianneschi,
  • Haomiao Xie,
  • Omar K. Farha

摘要

Controlling local chemical environments within porous crystalline materials is essential for selective adsorption and catalysis, yet remains difficult in stable frameworks with precisely oriented functional sites. Here we use reticular chemistry to programme tunable confinement in triazolate metal–organic frameworks constructed from Kuratowski-type Zn5Cl4 nodes. Linker geometry directs the formation of the ith-d topology, in which terminal Zn-bound groups point inwards to generate confined and chemically addressable pores. This strategy yields two isoreticular frameworks, NU-6000 and NU-6001, with distinct cage dimensions and apertures, while preserving the same topology. Post-synthetic chloride-to-hydroxide exchange installs dense arrays of inward-facing Zn–OH groups without loss of crystallinity, enabling reversible CO2 chemisorption through bicarbonate formation. Single-crystal analysis of a CO2 adduct reveals that confinement imposes a geometric accessibility limit on reactive hydroxyl sites within the smallest cage of NU-6000. Under this confinement regime, NU-6000 exhibits strong low-pressure CO2 capture, including at 30 ppm, and achieves 61.4% site utilization at 420 ppm, among the highest reported for metal–organic frameworks under comparable conditions.