2.2.2. SynthesisThere are three pri

2.2.2. Synthesis
There are three primary methods of CNTs synthesis: arc discharge
(Iijima, 1991), chemical vapor deposition (CVD) (Kong
et al., 1998), and laser ablation (Guo et al., 1995). CNTs were first
obtained using carbon-arc discharge. Depending upon the catalyst
used, this method yields MWNTs or SWNTs with high yield (90%)
and gives better control over the dimensions of synthesized tubes
(diameter between 0.6 and 1.4 nm for SWNTs and about 10 nm for
MWNTs and tube length close to few microns). The high yield and
reproducibility make this method suitable for large-scale commercial
synthesis. Chemical vapor deposition, much like arc discharge,
is also catalyst dependent and results in small diameter CNTs.
Though the yield of CNTs is comparatively lower, the resulting
CNTs are much cleaner needing less cleanup of soot and crude
products. Laser ablation gives the cleanest CNT though at a higher
price and lower yield with SWNT diameters of 1–2 nm. All these
synthesis methods result in a mixture of metallic and semi-conducting
CNTs. Now, issues that still remain to be addressed are:
(1) separation of CNTs from impurities which usually require harsh
treatments that often damage CNTs resulting in shortened length
or defected CNT surfaces, (2) the separation of metallic CNTs from
semi-conductive CNTs and (3) reducing the formation of CNT bundles
which occurs naturally due to van der Waals attractions. CNT
cleanup approaches can vary depending on the initial method of
synthesis. Separation of metallic and semi-conductive CNTs can
be done through selective functionalization (Maeda et al., 2008),
selective destruction by electrical heating (Collins et al., 2001), or
separation by density gradient ultracentrifugation (Lipscomb
et al., 2011), among others (Scheibe et al., 2011). To decrease bundle
formation, CNTs can be functionalized with chemical groups or
suspended in a surfactant containing solution