Luttinger Parameter g for Metallic Carbon Nanotubes and Related Systems

A.R. Goñi; C. Dekker; C. Kallin; C. Kane; F.D.M. Haldane; J. Voit; J.W. Mintmire; M. Bockrath; N. Hamada; Q.P. Li; R. Côté; R. Egger; R. Saito; R. Saito; S. Okada; W. Que; William Que; Z. Yao

research

Luttinger Parameter g for Metallic Carbon Nanotubes and Related Systems

Authors: A.R. Goñi
C. Dekker
C. Kallin
C. Kane
F.D.M. Haldane
J. Voit
J.W. Mintmire
M. Bockrath
N. Hamada
Q.P. Li
R. Côté
R. Egger
R. Saito
R. Saito
S. Okada
W. Que
William Que
Z. Yao
Publication date: 13 March 2003
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The random phase approximation (RPA) theory is used to derive the Luttinger parameter g for metallic carbon nanotubes. The results are consistent with the Tomonaga-Luttinger models. All metallic carbon nanotubes, regardless if they are armchair tubes, zigzag tubes, or chiral tubes, should have the same Luttinger parameter g. However, a (10,10) carbon peapod should have a smaller g value than a (10,10) carbon nanotube. Changing the Fermi level by applying a gate voltage has only a second order effect on the g value. RPA theory is a valid approach to calculate plasmon energy in carbon nanotube systems, regardless if the ground state is a Luttinger liquid or Fermi liquid. (This paper was published in PRB 66, 193405 (2002). However, Eqs. (6), (9), and (19) were misprinted there.)Comment: 2 figure

Similar works

Full text

Available Versions

Crossref

Last time updated on 02/01/2020