Carbon
Nanotubes as Electrically Active Nanoreactors
for Multi-Step Inorganic Synthesis: Sequential Transformations of
Molecules to Nanoclusters and Nanoclusters to Nanoribbons
posted on 2016-06-03, 00:00authored byAkos Botos, Johannes Biskupek, Thomas
W. Chamberlain, Graham A. Rance, Craig T. Stoppiello, Jeremy Sloan, Zheng Liu, Kazutomo Suenaga, Ute Kaiser, Andrei N. Khlobystov
In organic synthesis,
the composition and structure of products
are predetermined by the reaction conditions; however, the synthesis
of well-defined inorganic nanostructures often presents a significant
challenge yielding nonstoichiometric or polymorphic products. In this
study, confinement in the nanoscale cavities of single-walled carbon
nanotubes (SWNTs) provides a new approach for multistep inorganic
synthesis where sequential chemical transformations take place within
the same nanotube. In the first step, SWNTs donate electrons to reactant
iodine molecules (I2), transforming them to iodide anions
(I–). These then react with metal hexacarbonyls
(M(CO)6, M = Mo or W) in the next step, yielding anionic
nanoclusters [M6I14]2–, the
size and composition of which are strictly dictated by the nanotube
cavity, as demonstrated by aberration-corrected high resolution transmission
electron microscopy, scanning transmission electron microscopy, and
energy dispersive X-ray spectroscopy. Atoms in the nanoclusters [M6I14]2– are arranged in a perfect
octahedral geometry and can engage in further chemical reactions within
the nanotube, either reacting with each other leading to a new polymeric
phase of molybdenum iodide [Mo6I12]n or with hydrogen sulfide gas giving rise to nanoribbons
of molybdenum/tungsten disulfide [MS2]n in the third step of the synthesis. Electron microscopy measurements
demonstrate that the products of the multistep inorganic transformations
are precisely controlled by the SWNT nanoreactor with complementary
Raman spectroscopy revealing the remarkable property of SWNTs to act
as a reservoir of electrons during the chemical transformation. The
electron transfer from the host nanotube to the reacting guest molecules
is essential for stabilizing the anionic metal iodide nanoclusters
and for their further transformation to metal disulfide nanoribbons
synthesized in the nanotubes in high yield.