posted on 2019-08-05, 20:46authored byXing Huang, Ramzi Farra, Robert Schlögl, Marc-Georg Willinger
Understanding the
growth mechanism of carbon nanotubes (CNTs) has
been long pursued since its discovery. With recent integration of
in situ techniques into the study of CNT growth, important insights
about the growth mechanism of CNT have been generated, which have
improved our understanding significantly. However, previous in situ
experiments were mainly conducted at low pressures which were far
from the practical conditions. Direct information about the growth
dynamics under relevant conditions is still absent and thus is highly
desirable. In this work, we report atomic-scale observations of multiwalled
CNT (MWCNT) growth and termination at near ambient pressure by in
situ transmission electron microscopy. On the basis of the real-time
imaging, we are able to reveal that the working catalyst is constantly
reshaping at its apex during catalyzing CNT growth, whereas at the
base the catalyst remains faceted and barely shows any morphological
change. The active catalyst is identified as crystalline Fe3C, based on lattice fringes that can be imaged during growth. However,
the oscillatory growth behavior of the CNT and the structural dynamics
of the apex area strongly indicate that the carbon concentration in
the catalyst particle is fluctuating during the course of CNT growth.
Extended observations further reveal that the catalyst splitting can
occur: whereas the majority of the catalyst stays at the base and
continues catalyzing CNT growth, a small portion of it gets trapped
inside of the growing nanotube. The catalyst splitting can take place
multiple times, leading to shrinkage of both, catalyst size and diameter
of CNT, and finally the growth termination of CNT due to the full
coverage of the catalyst by carbon layers. Additionally, in situ observations
show two more scenarios for the growth termination, that is, out-migration
of the catalyst from the growing nanotube induced by (i) Oswald ripening
and (ii) weakened adhesion strength between the catalyst and CNT.