Nature Communications (May 2024)

Inward motion of diamond nanoparticles inside an iron crystal

  • Yuecun Wang,
  • Xudong Wang,
  • Jun Ding,
  • Beiming Liang,
  • Lingling Zuo,
  • Shaochuan Zheng,
  • Longchao Huang,
  • Wei Xu,
  • Chuanwei Fan,
  • Zhanqiang Duan,
  • Chunde Jia,
  • Rui Zheng,
  • Zhang Liu,
  • Wei Zhang,
  • Ju Li,
  • En Ma,
  • Zhiwei Shan

DOI
https://doi.org/10.1038/s41467-024-48692-5
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 9

Abstract

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Abstract In the absence of externally applied mechanical loading, it would seem counterintuitive that a solid particle sitting on the surface of another solid could not only sink into the latter, but also continue its rigid-body motion towards the interior, reaching a depth as distant as thousands of times the particle diameter. Here, we demonstrate such a case using in situ microscopic as well as bulk experiments, in which diamond nanoparticles ~100 nm in size move into iron up to millimeter depth, at a temperature about half of the melting point of iron. Each diamond nanoparticle is nudged as a whole, in a displacive motion towards the iron interior, due to a local stress induced by the accumulation of iron atoms diffusing around the particle via a short and easy interfacial channel. Our discovery underscores an unusual mass transport mode in solids, in addition to the familiar diffusion of individual atoms.