Abstract
To realize single-walled carbon nanotube (SWCNT) chiral selective growth, elucidating the mechanism of SWCNT chirality selectivity is important. For this purpose, an accurate evaluation method for evaluating the chirality distribution of grown SWCNTs without post-growth processing or liquid-dispersion of SWCNTs is indispensable. Here, we used photoluminescence spectroscopy to directly measure the chirality distributions of individual semiconducting SWCNTs suspended on a pillar-patterned substrate. The number of chirality-assigned SWCNTs was up to 332 and 17 chirality types with the chiral angles ranging from to were detected. The growth yield of SWCNTs was confirmed to primarily depends on the chiral angle in accordance with the screw dislocation model. Furthermore, when higher-yield chiralities are selected, the chiral angle distribution with a peak corresponding to near-armchair SWCNTs is well fitted with a model that incorporates the thermodynamic effect at the SWCNT-catalyst interface into the kink growth-based kinetic model. Our quantitative and statistical data provide new insights into SWCNT growth mechanism as well as experimental confirmation of theoretical predictions.
Highlights
Single-walled carbon nanotubes (SWCNTs) [1] are nanoscale tubular materials that exhibit excellent electrical and optical properties because of their pseudo-one-dimensional electronic states [2]
We evaluated the distribution of single-walled carbon nanotube (SWCNT) chirality using PL mapping
When two or more semiconducting SWCNTs are bundled and bridged, multiple emission spots are observed in the PL map [20]
Summary
Single-walled carbon nanotubes (SWCNTs) [1] are nanoscale tubular materials that exhibit excellent electrical and optical properties because of their pseudo-one-dimensional electronic states [2]. Their growth mechanism is interesting: they grow in a one-dimensional axial direction in the presence of nanoparticles “catalysts” [2]. Chirality control of SWCNTs has not been established for growth using conventional metal catalysts, such as Fe, Co and Ni, which allow high production efficiency and are important because of their practicality, and growth occurs for only a limited time. Further research on the growth mechanisms for SWCNTs is necessary, with the aim of improving growth control
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