Variations in the microstructure and electrical resistance of the SWCNT films under consecutive photoflash exposures

Abstract A film of unpurified single-walled carbon nanotubes (SWCNTs) synthesized by the floating catalyst method using ferrocene as the catalyst precursor was subjected to different numbers of flashes and the products were studied. In addition to the remaining SWCNTs, Fe 2 SiO 4 particles covered with amorphous carbon were found to attach on the SWCNTs, and the size increased with flash numbers. Fe 2 SiO 4 arose from the oxidation of Fe 3 C, a ferrocene-induced catalyst particle embedded in the SWCNTs, where Si provided by SiO 2 released from the mullite tube at 1200 °C during SWCNT growth. The amorphous carbon coating was attributed to insufficient time of the precipitated carbon to crystallize during rapid cooling after the flash. Variation of the Raman I D / I G ratio from an initial value of 0.035 to 0.025 after 100 flashes was due to competition between the removal of carbon from the nanotubes and the formation of amorphous carbon on the Fe 2 SiO 4 particle surface. The electrical resistance of the SWCNT film increased with the number of flashes but the change became progressively smaller, with the increment decreasing from 17.5% to 0.2%. Similar experiments using purified SWCNTs were performed, and no such particles were observed.

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