Position of K atoms in doped single-walled carbon nanotube crystals

Guanghua Gao; Tahir Çağin; William A. Goddard

doi:10.1103/PhysRevLett.80.5556

Position of K atoms in doped single-walled carbon nanotube crystals

Guanghua Gao
, Tahir Çağin
, William A. Goddard

Beckman Institute

Research output: Contribution to journal › Article › peer-review

Abstract

Recent experiments by Lee et al. [Nature (London) 363, 255 (1997)] show that doping carbon single-wall nanotube (SWNT) ropes with K, Rb, or Br₂ leads to metallic conductivity, but the structure and properties are not known. We used molecular dynamics to predict structures and properties which should help motivate and interpret experiments on SWNT/K. We find the optimum stoichiometry to be KC₁₆ if the K cannot penetrate the tubes and K₁ C₁₀ (K^exo₅ C^endo₃ C₈₀, 3 within the tube) if they can. We predict the optimum structure and the associated powder-diffraction x-ray pattern expected for K_n C₉₀ from n = 0−10 (optimum is n = 5). The Young’s modulus per tube along the tube axis varies from 640 to 525 GPa for n = 0 to 5.

Original language	English
Pages (from-to)	5556-5559
Number of pages	4
Journal	Physical Review Letters
Volume	80
Issue number	25
DOIs	https://doi.org/10.1103/PhysRevLett.80.5556
Publication status	Published - 1 Jan 1998
Externally published	Yes

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title = "Position of K atoms in doped single-walled carbon nanotube crystals",

abstract = "Recent experiments by Lee et al. [Nature (London) 363, 255 (1997)] show that doping carbon single-wall nanotube (SWNT) ropes with K, Rb, or Br2 leads to metallic conductivity, but the structure and properties are not known. We used molecular dynamics to predict structures and properties which should help motivate and interpret experiments on SWNT/K. We find the optimum stoichiometry to be KC16 if the K cannot penetrate the tubes and K1 C10 (Kexo5 Cendo3 C80, 3 within the tube) if they can. We predict the optimum structure and the associated powder-diffraction x-ray pattern expected for Kn C90 from n = 0−10 (optimum is n = 5). The Young{\textquoteright}s modulus per tube along the tube axis varies from 640 to 525 GPa for n = 0 to 5.",

author = "Guanghua Gao and Tahir {\c C}ağin and Goddard, \{William A.\}",

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AU - Çağin, Tahir

AU - Goddard, William A.

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N2 - Recent experiments by Lee et al. [Nature (London) 363, 255 (1997)] show that doping carbon single-wall nanotube (SWNT) ropes with K, Rb, or Br2 leads to metallic conductivity, but the structure and properties are not known. We used molecular dynamics to predict structures and properties which should help motivate and interpret experiments on SWNT/K. We find the optimum stoichiometry to be KC16 if the K cannot penetrate the tubes and K1 C10 (Kexo5 Cendo3 C80, 3 within the tube) if they can. We predict the optimum structure and the associated powder-diffraction x-ray pattern expected for Kn C90 from n = 0−10 (optimum is n = 5). The Young’s modulus per tube along the tube axis varies from 640 to 525 GPa for n = 0 to 5.

AB - Recent experiments by Lee et al. [Nature (London) 363, 255 (1997)] show that doping carbon single-wall nanotube (SWNT) ropes with K, Rb, or Br2 leads to metallic conductivity, but the structure and properties are not known. We used molecular dynamics to predict structures and properties which should help motivate and interpret experiments on SWNT/K. We find the optimum stoichiometry to be KC16 if the K cannot penetrate the tubes and K1 C10 (Kexo5 Cendo3 C80, 3 within the tube) if they can. We predict the optimum structure and the associated powder-diffraction x-ray pattern expected for Kn C90 from n = 0−10 (optimum is n = 5). The Young’s modulus per tube along the tube axis varies from 640 to 525 GPa for n = 0 to 5.

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Position of K atoms in doped single-walled carbon nanotube crystals

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