In the present study, we report the synthesis of carbon nanotubes (CNTs) using a new natural precursor: castor oil. The CNTs were synthesized by spray pyrolysis of castor oil-ferrocene solution at 850°C under an Ar atmosphere. We also report the synthesis of carbon nitrogen (C-N) nanotubes using castor oilferrocene-ammonia precursor. The as-grown CNTs and C-N nanotubes were characterized through scanning and transmission electron microscopic techniques. Graphitic nanofibres (GNFs) were synthesized by thermal decomposition of acetylene (C 2 H 2 ) gas using Ni catalyst at 600°C. As-grown GNFs reveal both planar and helical morphology. We have investigated the structural and electrical properties of multi-walled CNTs (MWNTs)-polymer (polyacrylamide (PAM)) composites. The MWNTs-PAM composites were prepared using as purified, with ball milling and functionalized MWNTs by solution cast technique and characterized through SEM. A comparative study has been made on the electrical property of these MWNTs-PAM composites with different MWNTs loadings. It is shown that the ball milling and functionalization of MWNTs improves the dispersion of MWNTs into the polymer matrix. Enhanced electrical conductivity was observed for the MWNTs-PAM composites. Graphene samples were prepared by thermal exfoliation of graphite oxide. XRD analysis confirms the formation of graphene.
One of the most technically challenging barriers to the
widespread commercialization of hydrogen-fueled
devices and vehicles remains hydrogen storage. More environmentally
friendly and effective nonmetal catalysts are required to improve
hydrogen sorption. In this paper, through a combination of experiment
and theory, we evaluate and explore the catalytic effects of layered
graphene nanofibers toward hydrogen release of light metal hydrides
such as sodium alanate. Graphene nanofibers, especially the helical
kind, are found to considerably improve hydrogen release from NaAlH4, which is of significance for the further enhancement of
this practical material for environmentally friendly and effective
hydrogen storage applications. Using density functional theory, we
find that carbon sheet edges, regardless of whether they are of zigzag
or armchair type, can weaken Al–H bonds in sodium alanate,
which is believed to be due to a combination of NaAlH4 destabilization
and dissociation product stabilization. The helical form of graphene
nanofibers, with larger surface area and curved configuration, appears
to benefit the functionalization of carbon sheet edges. We believe
that our combined experimental and theoretical study will stimulate
more explorations of other microporous or mesoporous nanomaterials
with an abundance of exposed carbon edges in the application of practical
complex light metal hydride systems.
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