Polyyne ring nucleus growth model for single-layer carbon nanotubes

Ching Hwa Kiang; William A. Goddard

doi:10.1103/PhysRevLett.76.2515

Polyyne ring nucleus growth model for single-layer carbon nanotubes

Ching Hwa Kiang
, William A. Goddard

Division of Chemistry and Chemical Engineering
IBM Almaden Research Center
Massachusetts Institute of Technology

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We propose, based on recent experimental results, a polyyne ring nucleus (PRN) growth model for the synthesis of single-layer nanotubes (SLN's). The PRN model assumes that (i) the critical nuclei are the planar carbon polyyne rings that are observed to be most stable for sizes in the range C₁₀ to C₄₀; (ii) Co_mC_n clusters (possibly charged) play the role of a catalyst by serving to add C₂ or other gas phase species into the growing tube; (iii) promoters such as S, Bi, and Pb serve to modify the rates for these processes by stabilizing the ring structure. We suggest experiments to test and amplify this PRN model, including a flow tube arrangement that might be useful for synthesizing more uniform SLN's.

langue originale	Anglais
Pages (de - à)	2515-2518
Nombre de pages	4
journal	Physical Review Letters
Volume	76
Numéro de publication	14
Les DOIs	https://doi.org/10.1103/PhysRevLett.76.2515
état	Publié - 1 déc. 1996
Modification externe	Oui

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title = "Polyyne ring nucleus growth model for single-layer carbon nanotubes",

abstract = "We propose, based on recent experimental results, a polyyne ring nucleus (PRN) growth model for the synthesis of single-layer nanotubes (SLN's). The PRN model assumes that (i) the critical nuclei are the planar carbon polyyne rings that are observed to be most stable for sizes in the range C10 to C40; (ii) ComCn clusters (possibly charged) play the role of a catalyst by serving to add C2 or other gas phase species into the growing tube; (iii) promoters such as S, Bi, and Pb serve to modify the rates for these processes by stabilizing the ring structure. We suggest experiments to test and amplify this PRN model, including a flow tube arrangement that might be useful for synthesizing more uniform SLN's.",

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AU - Goddard, William A.

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N2 - We propose, based on recent experimental results, a polyyne ring nucleus (PRN) growth model for the synthesis of single-layer nanotubes (SLN's). The PRN model assumes that (i) the critical nuclei are the planar carbon polyyne rings that are observed to be most stable for sizes in the range C10 to C40; (ii) ComCn clusters (possibly charged) play the role of a catalyst by serving to add C2 or other gas phase species into the growing tube; (iii) promoters such as S, Bi, and Pb serve to modify the rates for these processes by stabilizing the ring structure. We suggest experiments to test and amplify this PRN model, including a flow tube arrangement that might be useful for synthesizing more uniform SLN's.

AB - We propose, based on recent experimental results, a polyyne ring nucleus (PRN) growth model for the synthesis of single-layer nanotubes (SLN's). The PRN model assumes that (i) the critical nuclei are the planar carbon polyyne rings that are observed to be most stable for sizes in the range C10 to C40; (ii) ComCn clusters (possibly charged) play the role of a catalyst by serving to add C2 or other gas phase species into the growing tube; (iii) promoters such as S, Bi, and Pb serve to modify the rates for these processes by stabilizing the ring structure. We suggest experiments to test and amplify this PRN model, including a flow tube arrangement that might be useful for synthesizing more uniform SLN's.

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Polyyne ring nucleus growth model for single-layer carbon nanotubes

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