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Functional materials discovery using energy–structure–function maps

Author

Listed:
  • Angeles Pulido

    (Computational Systems Chemistry, School of Chemistry, University of Southampton)

  • Linjiang Chen

    (University of Liverpool)

  • Tomasz Kaczorowski

    (University of Liverpool)

  • Daniel Holden

    (University of Liverpool)

  • Marc A. Little

    (University of Liverpool)

  • Samantha Y. Chong

    (University of Liverpool)

  • Benjamin J. Slater

    (University of Liverpool)

  • David P. McMahon

    (Computational Systems Chemistry, School of Chemistry, University of Southampton)

  • Baltasar Bonillo

    (University of Liverpool)

  • Chloe J. Stackhouse

    (University of Liverpool)

  • Andrew Stephenson

    (University of Liverpool)

  • Christopher M. Kane

    (University of Liverpool)

  • Rob Clowes

    (University of Liverpool)

  • Tom Hasell

    (University of Liverpool)

  • Andrew I. Cooper

    (University of Liverpool)

  • Graeme M. Day

    (Computational Systems Chemistry, School of Chemistry, University of Southampton)

Abstract

Molecular crystals cannot be designed in the same manner as macroscopic objects, because they do not assemble according to simple, intuitive rules. Their structures result from the balance of many weak interactions, rather than from the strong and predictable bonding patterns found in metal–organic frameworks and covalent organic frameworks. Hence, design strategies that assume a topology or other structural blueprint will often fail. Here we combine computational crystal structure prediction and property prediction to build energy–structure–function maps that describe the possible structures and properties that are available to a candidate molecule. Using these maps, we identify a highly porous solid, which has the lowest density reported for a molecular crystal so far. Both the structure of the crystal and its physical properties, such as methane storage capacity and guest-molecule selectivity, are predicted using the molecular structure as the only input. More generally, energy–structure–function maps could be used to guide the experimental discovery of materials with any target function that can be calculated from predicted crystal structures, such as electronic structure or mechanical properties.

Suggested Citation

  • Angeles Pulido & Linjiang Chen & Tomasz Kaczorowski & Daniel Holden & Marc A. Little & Samantha Y. Chong & Benjamin J. Slater & David P. McMahon & Baltasar Bonillo & Chloe J. Stackhouse & Andrew Steph, 2017. "Functional materials discovery using energy–structure–function maps," Nature, Nature, vol. 543(7647), pages 657-664, March.
    • Handle: RePEc:nat:nature:v:543:y:2017:i:7647:d:10.1038_nature21419
    DOI: 10.1038/nature21419
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    Cited by:

    1. Xiaojun Ding & Jing Chen & Gang Ye, 2024. "Supramolecular polynuclear clusters sustained cubic hydrogen bonded frameworks with octahedral cages for reversible photochromism," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    2. Shimin Chen & Yan Ju & Yisi Yang & Fahui Xiang & Zizhu Yao & Hao Zhang & Yunbin Li & Yongfan Zhang & Shengchang Xiang & Banglin Chen & Zhangjing Zhang, 2024. "Multistate structures in a hydrogen-bonded polycatenation non-covalent organic framework with diverse resistive switching behaviors," Nature Communications, Nature, vol. 15(1), pages 1-11, December.

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