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On-surface synthesis of a doubly anti-aromatic carbon allotrope

Author

Listed:
  • Yueze Gao

    (Oxford University, Chemistry Research Laboratory)

  • Florian Albrecht

    (IBM Research Europe – Zürich)

  • Igor Rončević

    (Oxford University, Chemistry Research Laboratory
    Institute of Organic Chemistry and Biochemistry of the Czech Academy of Sciences)

  • Isaac Ettedgui

    (Oxford University, Chemistry Research Laboratory)

  • Paramveer Kumar

    (Oxford University, Chemistry Research Laboratory)

  • Lorel M. Scriven

    (Oxford University, Chemistry Research Laboratory)

  • Kirsten E. Christensen

    (Oxford University, Chemistry Research Laboratory)

  • Shantanu Mishra

    (IBM Research Europe – Zürich)

  • Luca Righetti

    (IBM Quantum, IBM Research – Zürich)

  • Max Rossmannek

    (IBM Quantum, IBM Research – Zürich)

  • Ivano Tavernelli

    (IBM Quantum, IBM Research – Zürich)

  • Harry L. Anderson

    (Oxford University, Chemistry Research Laboratory)

  • Leo Gross

    (IBM Research Europe – Zürich)

Abstract

Synthetic carbon allotropes such as graphene1, carbon nanotubes2 and fullerenes3 have revolutionized materials science and led to new technologies. Many hypothetical carbon allotropes have been discussed4, but few have been studied experimentally. Recently, unconventional synthetic strategies such as dynamic covalent chemistry5 and on-surface synthesis6 have been used to create new forms of carbon, including γ-graphyne7, fullerene polymers8, biphenylene networks9 and cyclocarbons10,11. Cyclo[N]carbons are molecular rings consisting of N carbon atoms12,13; the three that have been reported to date (N = 10, 14 and 18)10,11 are doubly aromatic, which prompts the question: is it possible to prepare doubly anti-aromatic versions? Here we report the synthesis and characterization of an anti-aromatic carbon allotrope, cyclo[16]carbon, by using tip-induced on-surface chemistry6. In addition to structural information from atomic force microscopy, we probed its electronic structure by recording orbital density maps14 with scanning tunnelling microscopy. The observation of bond-length alternation in cyclo[16]carbon confirms its double anti-aromaticity, in concordance with theory. The simple structure of C16 renders it an interesting model system for studying the limits of aromaticity, and its high reactivity makes it a promising precursor to novel carbon allotropes15.

Suggested Citation

  • Yueze Gao & Florian Albrecht & Igor Rončević & Isaac Ettedgui & Paramveer Kumar & Lorel M. Scriven & Kirsten E. Christensen & Shantanu Mishra & Luca Righetti & Max Rossmannek & Ivano Tavernelli & Harr, 2023. "On-surface synthesis of a doubly anti-aromatic carbon allotrope," Nature, Nature, vol. 623(7989), pages 977-981, November.
    • Handle: RePEc:nat:nature:v:623:y:2023:i:7989:d:10.1038_s41586-023-06566-8
    DOI: 10.1038/s41586-023-06566-8
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    Cited by:

    1. Luye Sun & Wei Zheng & Faming Kang & Wenze Gao & Tongde Wang & Guohua Gao & Wei Xu, 2024. "On-surface synthesis and characterization of anti-aromatic cyclo[12]carbon and cyclo[20]carbon," Nature Communications, Nature, vol. 15(1), pages 1-8, December.

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