Merged-nets enumeration for the systematic design of multicomponent reticular structures

Hao Jiang; Salma Benźaria; Norah Alsadun; Jiangtao Jia; Justyna Cźaban-Jóźwiak; Vincent Guillerm; Aleksander Shkurenko; Zeynabou Thiam; Mickaele Bonneau; Vijay K. Maka; Zhijie Chen; Zied Ouled Ameur; Michael O’Keeffe; Mohamed Eddaoudi

doi:10.1126/science.ads7866

Merged-nets enumeration for the systematic design of multicomponent reticular structures

Hao Jiang, Salma Benźaria, Norah Alsadun, Jiangtao Jia, Justyna Cźaban-Jóźwiak, Vincent Guillerm, Aleksander Shkurenko, Zeynabou Thiam, Mickaele Bonneau, Vijay K. Maka, Zhijie Chen, Zied Ouled Ameur, Michael O’Keeffe, Mohamed Eddaoudi^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Rational design of intricate multicomponent reticular structures is often hindered by the lack of suitable blueprint nets. We established the merged-net approach, proffering optimal balance between designability and complexity, as a systematic solution for the rational assembly of multicomponent structures. In this work, by methodically mapping node-net relationships among 53 basic edge-transitive nets, we conceived a signature net map to identify merging net pairs, resulting in the enumeration of 53 merged nets. We developed a practical design algorithm and proposed more than 100 multicomponent metal-organic framework platforms. The effectiveness of this approach is commended by the successful synthesis of four classes of materials, which is based on merging three-periodic nets with the four possible net periodicities. The construction of multicomponent materials based on derived nets of merged nets highlights the potential of the merged-net approach in accelerating the discovery of intricate reticular materials.

Original language	English (US)
Pages (from-to)	659-666
Number of pages	8
Journal	Journal of Bio-X Research
Volume	386
Issue number	6722
DOIs	https://doi.org/10.1126/science.ads7866
State	Published - Nov 8 2024

Bibliographical note

Publisher Copyright:
Copyright © 2024 the authors, some rights reserved; exclusive licensee American Association for the Advancement of Science.

ASJC Scopus subject areas

Biomedical Engineering
General Biochemistry, Genetics and Molecular Biology
Computer Science Applications

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Jiang, H., Benźaria, S., Alsadun, N., Jia, J., Cźaban-Jóźwiak, J., Guillerm, V., Shkurenko, A., Thiam, Z., Bonneau, M., Maka, V. K., Chen, Z., Ameur, Z. O., O’Keeffe, M., & Eddaoudi, M. (2024). Merged-nets enumeration for the systematic design of multicomponent reticular structures. Journal of Bio-X Research, 386(6722), 659-666. https://doi.org/10.1126/science.ads7866

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title = "Merged-nets enumeration for the systematic design of multicomponent reticular structures",

abstract = "Rational design of intricate multicomponent reticular structures is often hindered by the lack of suitable blueprint nets. We established the merged-net approach, proffering optimal balance between designability and complexity, as a systematic solution for the rational assembly of multicomponent structures. In this work, by methodically mapping node-net relationships among 53 basic edge-transitive nets, we conceived a signature net map to identify merging net pairs, resulting in the enumeration of 53 merged nets. We developed a practical design algorithm and proposed more than 100 multicomponent metal-organic framework platforms. The effectiveness of this approach is commended by the successful synthesis of four classes of materials, which is based on merging three-periodic nets with the four possible net periodicities. The construction of multicomponent materials based on derived nets of merged nets highlights the potential of the merged-net approach in accelerating the discovery of intricate reticular materials.",

author = "Hao Jiang and Salma Ben{\'z}aria and Norah Alsadun and Jiangtao Jia and Justyna C{\'z}aban-J{\'o}{\'z}wiak and Vincent Guillerm and Aleksander Shkurenko and Zeynabou Thiam and Mickaele Bonneau and Maka, \{Vijay K.\} and Zhijie Chen and Ameur, \{Zied Ouled\} and Michael O{\textquoteright}Keeffe and Mohamed Eddaoudi",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 the authors, some rights reserved; exclusive licensee American Association for the Advancement of Science.",

year = "2024",

month = nov,

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doi = "10.1126/science.ads7866",

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Jiang, H, Benźaria, S, Alsadun, N, Jia, J, Cźaban-Jóźwiak, J, Guillerm, V , Shkurenko, A, Thiam, Z, Bonneau, M , Maka, VK, Chen, Z, Ameur, ZO, O’Keeffe, M & Eddaoudi, M 2024, 'Merged-nets enumeration for the systematic design of multicomponent reticular structures', Journal of Bio-X Research, vol. 386, no. 6722, pp. 659-666. https://doi.org/10.1126/science.ads7866

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AU - Jiang, Hao

AU - Benźaria, Salma

AU - Alsadun, Norah

AU - Jia, Jiangtao

AU - Cźaban-Jóźwiak, Justyna

AU - Guillerm, Vincent

AU - Shkurenko, Aleksander

AU - Thiam, Zeynabou

AU - Bonneau, Mickaele

AU - Maka, Vijay K.

AU - Chen, Zhijie

AU - Ameur, Zied Ouled

AU - O’Keeffe, Michael

AU - Eddaoudi, Mohamed

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AB - Rational design of intricate multicomponent reticular structures is often hindered by the lack of suitable blueprint nets. We established the merged-net approach, proffering optimal balance between designability and complexity, as a systematic solution for the rational assembly of multicomponent structures. In this work, by methodically mapping node-net relationships among 53 basic edge-transitive nets, we conceived a signature net map to identify merging net pairs, resulting in the enumeration of 53 merged nets. We developed a practical design algorithm and proposed more than 100 multicomponent metal-organic framework platforms. The effectiveness of this approach is commended by the successful synthesis of four classes of materials, which is based on merging three-periodic nets with the four possible net periodicities. The construction of multicomponent materials based on derived nets of merged nets highlights the potential of the merged-net approach in accelerating the discovery of intricate reticular materials.

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Merged-nets enumeration for the systematic design of multicomponent reticular structures

Abstract

Bibliographical note

ASJC Scopus subject areas

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