Issue 47, 2020

Integration of 3D nanographene into mesoporous germanium

Abstract

Graphene is a key material of interest for the modification of physicochemical surface properties. However, its flat surface is a limitation for applications requiring a high specific surface area. This restriction may be overcome by integrating 2D materials in a 3D structure. Here, a strategy for the controlled synthesis of Graphene-Mesoporous Germanium (Gr-MP-Ge) nanomaterials is presented. Bipolar electrochemical etching and chemical vapor infiltration were employed, respectively, for the nanostructuration of Ge substrate and subsequent 3D nanographene coating. While Raman spectroscopy reveals a tunable domain size of nanographene with the treatment temperature, transmission electron microscopy data confirm that the crystallinity of Gr-MP-Ge is preserved. X-ray photoelectron spectroscopy indicates the non-covalent bonding of carbon to Ge for Gr-MP-Ge. State-of-the-art molecular dynamics modeling provides a deeper understanding of the synthesis process through the presence of radicals. The successful synthesis of these nanomaterials offers the integration of nanographene into a 3D structure with a high aspect ratio and light weight, thereby opening avenues to a variety of applications for this versatile nanomaterial.

Graphical abstract: Integration of 3D nanographene into mesoporous germanium

Supplementary files

Article information

Article type
Paper
Submitted
01 Jul 2020
Accepted
27 Sep 2020
First published
23 Oct 2020

Nanoscale, 2020,12, 23984-23994

Integration of 3D nanographene into mesoporous germanium

S. Sauze, M. R. Aziziyan, P. Brault, G. Kolhatkar, A. Ruediger, A. Korinek, D. Machon, R. Arès and A. Boucherif, Nanoscale, 2020, 12, 23984 DOI: 10.1039/D0NR04937A

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