화학공학소재연구정보센터
Journal of Physical Chemistry B, Vol.108, No.14, 4385-4393, 2004
Combing and bending of carbon nanotube arrays with confined microfluidic flow on patterned surfaces
Ordered arrays of carbon nanombes in bent and straight states were prepared using "wet" deposition of nanotube solutions on a patterned surface. This approach provided a means for the formation of highly oriented and textured nanotube arrays of different types. Moreover, under certain conditions, nanotube loops of different shapes were formed on amine-terminated silicon surface stripes. Atomic force microscopy observations indicated that the majority of the deposited nanombes (up to 90%) are uniformly oriented and up to 40% of aligned nanotubes are folded into different nanoscale shapes (open and closed loops with 200-300 nm radius of curvature). We suggested that the dewetting of the SAM-confined liquid film was responsible for the alignment of carbon nanotubes and for the formation of the looped nanotubes. The instability of a receding contact line caused water microdroplets behind the dewetting film, which could serve as nuclei for nanotube trapping. The nanotubes pinned to the functionalized surface can be trapped by these drying microdroplets and bent along their shrinking circumference. In addition, highly packed ordered arrays of carbon nanotubes were formed by casting from solution on tilted patterned substrates. The preparation of the ordered arrays of uniform nanotube loops or woven nanotube stripes may be useful in microelectronic and microelectromechanical devices, where tunable electronic and surface properties result from different nanotube shapes, locations, and orientations.