posted on 2013-06-12, 00:00authored byStephen A. Steiner, Richard Li, Brian L. Wardle
Hierarchical carbon fibers (CFs)
sheathed with radial arrays of carbon nanotubes (CNTs) are promising
candidates for improving the intra- and interlaminar properties of
advanced fiber-reinforced composites (e.g., graphite/epoxy) and for
high-surface-area electrodes for battery and supercapacitor architectures.
While CVD growth of CNTs on CFs has been previously shown to improve
the apparent shear strength between fibers and polymer matrices (up
to 60%), this has to date been achieved only at the expense of significant
reductions in tensile strength (∼30–50%) and stiffness
(∼10–20%) of the underlying fiber. Here we demonstrate
two approaches for growing aligned and unaligned CNTs on CFs that
enable preservation of fiber strength and stiffness. We observe that
CVD-induced reduction of fiber strength and stiffness is primarily
attributable to mechanochemical reorganization of the underlying fiber
when heated untensioned above ∼550 °C in both hydrocarbon-containing
and inert atmospheres. We show that tensioning fibers to ≥12%
of tensile strength during CVD enables aligned CNT growth while simultaneously
preserving fiber strength and stiffness even at growth temperatures
>700
°C. We also show that CNT growth employing CO2/acetylene
at 480 °C without tensioningbelow the identified critical
strength-loss temperaturepreserves fiber strength. These results
highlight previously unidentified mechanisms underlying synthesis
of hierarchical CFs and demonstrate scalable, facile methods for doing
so.