Reactions of the inner surface of carbon nanotubes and nanoprotrusion processes imaged at the atomic
Author: ["Thomas W. Chamberlain","Jannik C. Meyer","Johannes Biskupek","Jens Leschner","Adriano Santana","Nicholas A. Besley","Elena Bichoutskaia","Ute Kaiser","Andrei N. Khlobystov"]
Publication: Nature Chemistry
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Abstract
Although the outer surface of single-walled carbon nanotubes (atomically thin cylinders of carbon) can be involved in a wide range of chemical reactions, it is generally thought that the interior surface of nanotubes is unreactive. In this study, we show that in the presence of catalytically active atoms of rhenium inserted into nanotubes, the nanotube sidewall can be engaged in chemical reactions from the inside. Aberration-corrected high-resolution transmission electron microscopy operated at 80 keV allows visualization of the formation of nanometre-sized hollow protrusions on the nanotube sidewall at the atomic level in real time at ambient temperature. Our direct observations and theoretical modelling demonstrate that the nanoprotrusions are formed in three stages: (i) metal-assisted deformation and rupture of the nanotube sidewall, (ii) the fast formation of a metastable asymmetric nanoprotrusion with an open edge and (iii) a slow symmetrization process that leads to a stable closed nanoprotrusion. The outer surfaces of single-walled carbon nanotubes (SWNTs) are known to participate in a range of chemical reactions, but the inner surfaces have so far been thought to be somewhat unreactive. Now, it has been shown that electron-beam irradiation of rhenium–fullerene complexes inside SWNTs can trigger reactions at the inner wall to form protrusions on the nanotube surface.
Cite this article
Chamberlain, T., Meyer, J., Biskupek, J. et al. Reactions of the inner surface of carbon nanotubes and nanoprotrusion processes imaged at the atomic scale. Nature Chem 3, 732–737 (2011). https://doi.org/10.1038/nchem.1115
