Assignment of (n, m) Raman and optical features of metallic single-walled carbon nanotubes

BibTex:
Research areas:	Uncategorized	Year:	2003
Type of Publication:	Article
Authors:	M. S. Strano, E. H. Haroz S. K. Doorn
Journal:	Nano Letters	Volume:	3
Number:	8
Month:	AUG 2003

@article{RefWorks:854, author = "M. S. Strano,S. K. Doorn,E. H. Haroz,C. Kittrell,R. H. Hauge,R. E. Smalley", abstract = "Raman spectroscopy performed between 565 and 627 nm and also between 458- and 514.5-nm laser excitation was used to map the lowest-energy van Hove singularities of metallic single-walled carbon nanotubes suspended in aqueous solution using sodium dodecyl sulfate. The interband transitions of distinct metallic nanotubes were observed directly and assigned using a correlation of the diameter and radial breathing mode (RBM) in the Raman spectrum. The results were extrapolated to all metallic nanotubes using a generalized scaling derived from the tight-binding formalism and were shown to be valid for describing the electronic structure of semiconducting nanotubes as well. The model results are compared using excitation profiles outside of the above-reported scan ranges with excellent agreement between observed and predicted profile widths and transition energies.", isbn = "1530-6984", journal = "Nano Letters", month = "AUG 2003", note = "PT: J; TC: 159; UT: WOS:000184892400021", number = "8", title = "{A}ssignment of (n, m) {R}aman and optical features of metallic single-walled carbon nanotubes", volume = "3", year = "2003", }
Note:	PT: J; TC: 159; UT: WOS:000184892400021
Abstract:	Raman spectroscopy performed between 565 and 627 nm and also between 458- and 514.5-nm laser excitation was used to map the lowest-energy van Hove singularities of metallic single-walled carbon nanotubes suspended in aqueous solution using sodium dodecyl sulfate. The interband transitions of distinct metallic nanotubes were observed directly and assigned using a correlation of the diameter and radial breathing mode (RBM) in the Raman spectrum. The results were extrapolated to all metallic nanotubes using a generalized scaling derived from the tight-binding formalism and were shown to be valid for describing the electronic structure of semiconducting nanotubes as well. The model results are compared using excitation profiles outside of the above-reported scan ranges with excellent agreement between observed and predicted profile widths and transition energies.

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