Summary:
We produce ordered surface nanostructures on azimuthally rotating HOPG(0001) by irradiation with low-energy ion beams. Thus, small dots at low fluences evolve into cellular structures at large fluences. This transition is a consequence of the fast growth of dots and their subsequent concatenation to form walls along the grain boundaries, leading to cells. The walls compete and ripen with continued ion beam irradiation, resulting in both coarsening and roughening of the cell pattern. We reproduce the same morphological and scaling behavior using different ions, Kr or Ar, so the mechanisms involved in pattern formation and coarsening are robust. We compare the experimental findings with simulations of a nonlinear continuum model based on ion-driven viscous flow, which reproduces many qualitative properties seen in the experiments. Such a comparison underscores the need for a suitable consideration of both external noise and the grain structure of the target to fully account for the large-scale properties of the process.
Spanish layman's summary:
Un modelo matemático inspirado en la mecánica de fluidos explica la formación y evolución de patrones por irradiación de Grafito pirolítico altamente orientado. Estas estructuras autoorganizadas tienen varias aplicaciones en microscopía y nanotecnología.
English layman's summary:
A mathematical model inspired by fluid mechanics explains the formation and evolution of patterns by irradiation of Highly Oriented Pyrolytic Graphite (HOPG). These self-organizing structures have various applications in microscopy and nanotechnology.
JCR Impact Factor and WoS quartile: 3,700 - Q2 (2022)
DOI reference:
https://doi.org/10.1103/PhysRevB.105.085413
Published on paper: February 2022.
Published on-line: February 2022.
Citation:
E. Lee, J. Seo, J. Muñoz-Garcia, M. Castro, R. Cuerno, J.-S. Kim, Nanopatterning of rotating highly oriented pyrolytic graphite (0001) surfaces by ion beam irradiation: experiments and modeling. Physical Review B. Vol. 105, nº. 8, pp. 085413-1 - 085413-17, February 2022. [Online: February 2022]
