<p>Nanodiamonds hosting colour centres are promising building blocks for quantum technologies, enabling advances in quantum computation<sup><CitationRef CitationID="CR1">1</CitationRef>,<CitationRef CitationID="CR2">2</CitationRef></sup>, nanoscale NMR spectroscopy<sup><CitationRef AdditionalCitationIDS="CR4 CR5" CitationID="CR3">3</CitationRef>–<CitationRef CitationID="CR6">6</CitationRef></sup>, single-spin magnetometry<sup><CitationRef CitationID="CR7">7</CitationRef>,<CitationRef CitationID="CR8">8</CitationRef></sup>, wide-field quantum imaging<sup><CitationRef CitationID="CR9">9</CitationRef></sup> and single-photon sources<sup><CitationRef CitationID="CR10">10</CitationRef>,<CitationRef CitationID="CR11">11</CitationRef></sup>. However, the controlled bottom-up synthesis of ultrasmall and structurally uniform nanodiamonds has remained a challenge, with existing methods producing heterogeneous materials that vary in size, morphology, impurity content and defect quality. Here we show that well-defined, hydrogen-terminated molecular nanographenes serve as chemically confined precursors for high-pressure, high-temperature synthesis of ultrasmall (3–4 nm), monodisperse and highly crystalline molecular nanodiamonds with only a single <i>sp</i><sup>2</sup> surface reconstruction and produced on a milligram scale. The same bottom-up platform also enables a two-component strategy for incorporating silicon- and germanium-based colour centres during synthesis, yielding SiV<sup>−</sup> and GeV<sup>−</sup> emitters without ion implantation, irradiation or post-treatment. Because the nanographene precursor defines both the confined carbon framework and the hydrogen content, this approach provides intrinsic, precursor-level control over nanodiamond size and composition, particularly in the low-nanometre regime relevant for biological and quantum sensing. Molecular nanographenes, ultralarge polycyclic aromatic hydrocarbons, therefore, establish a scalable and modular route to high-quality molecular and fluorescent nanodiamonds and offer a general design principle for tailored quantum materials and nanoscale devices.</p>

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Bottom-up synthesis of molecular nanodiamond from nanographene

  • Jiaxu Liang,
  • Christopher P. Ender,
  • Nancy C. Forero-Martinez,
  • Ilyes Batatia,
  • Jingyi Liu,
  • Xin Yang,
  • Raul Gonzalez Brouwer,
  • Lev Kazak,
  • Rémi Blinder,
  • Leonardo Cancellara,
  • Nadezda V. Tarakina,
  • Yizhi Liu,
  • Tobias Eklund,
  • Mangalika Sinha,
  • Sarah Köster,
  • Shrikant Bhat,
  • Fabian Rohmann,
  • Andreas Tangemann,
  • Kilian Lee Gallo,
  • Rüdiger Berger,
  • Robert Farla,
  • Alexander Kubanek,
  • Katrin Amann-Winkel,
  • Manfred Wagner,
  • Fedor Jelezko,
  • Klaus Müllen,
  • Gábor Csányi,
  • Robinson Cortes-Huerto,
  • Yingke Wu,
  • Tanja Weil

摘要

Nanodiamonds hosting colour centres are promising building blocks for quantum technologies, enabling advances in quantum computation1,2, nanoscale NMR spectroscopy36, single-spin magnetometry7,8, wide-field quantum imaging9 and single-photon sources10,11. However, the controlled bottom-up synthesis of ultrasmall and structurally uniform nanodiamonds has remained a challenge, with existing methods producing heterogeneous materials that vary in size, morphology, impurity content and defect quality. Here we show that well-defined, hydrogen-terminated molecular nanographenes serve as chemically confined precursors for high-pressure, high-temperature synthesis of ultrasmall (3–4 nm), monodisperse and highly crystalline molecular nanodiamonds with only a single sp2 surface reconstruction and produced on a milligram scale. The same bottom-up platform also enables a two-component strategy for incorporating silicon- and germanium-based colour centres during synthesis, yielding SiV and GeV emitters without ion implantation, irradiation or post-treatment. Because the nanographene precursor defines both the confined carbon framework and the hydrogen content, this approach provides intrinsic, precursor-level control over nanodiamond size and composition, particularly in the low-nanometre regime relevant for biological and quantum sensing. Molecular nanographenes, ultralarge polycyclic aromatic hydrocarbons, therefore, establish a scalable and modular route to high-quality molecular and fluorescent nanodiamonds and offer a general design principle for tailored quantum materials and nanoscale devices.