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A zeolite family with expanding structural complexity and embedded isoreticular structures

Research output: Contribution to journalArticlepeer-review

  • Peng Guo
  • Jiho Shin
  • Alex G. Greenaway
  • Jung Gi Min
  • Jie Su
  • Hyun June Choi
  • Leifeng Liu
  • Professor Paul Cox
  • Suk Bong Hong
  • Paul A. Wright
  • Xiaodong Zou
The prediction and synthesis of new crystal structures enable the targeted preparation of materials with desired properties. Among porous solids, this has been achieved for metal–organic frameworks 1, 2, 3, but not for the more widely applicable zeolites 4, 5, where new materials are usually discovered using exploratory synthesis. Although millions of hypothetical zeolite structures have been proposed 6, 7, not enough is known about their synthesis mechanism to allow any given structure to be prepared. Here we present an approach that combines structure solution with structure prediction, and inspires the targeted synthesis of new super-complex zeolites. We used electron diffraction to identify a family of related structures and to discover the structural ‘coding’ within them. This allowed us to determine the complex, and previously unknown, structure of zeolite ZSM-25 (ref. 8), which has the largest unit-cell volume of all known zeolites (91,554 cubic ångströms) and demonstrates selective CO2 adsorption. By extending our method, we were able to predict other members of a family of increasingly complex, but structurally related, zeolites and to synthesize two more-complex zeolites in the family, PST-20 and PST-25, with much larger cell volumes (166,988 and 275,178 cubic ångströms, respectively) and similar selective adsorption properties. Members of this family have the same symmetry, but an expanding unit cell, and are related by hitherto unrecognized structural principles; we call these family members embedded isoreticular zeolite structures.
Original languageEnglish
Pages (from-to)74-78
Number of pages5
JournalNature
Volume524
Issue number7563
Early online date15 Jul 2015
DOIs
Publication statusPublished - 6 Aug 2015

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