Physical Properties of Carbon Nanotubes

The following sections are included:

• Preface

• Contents

Carbon materials are found in variety forms such as graphite, diamond, carbon fibers, fullerenes, and carbon nanotubes. The reason why carbon assumes many structural forms is that a carbon atom can form several distinct types of valence bonds, where the chemical bonds refer to the hybridization of orbitals by physicists. This chapter introduces the history of carbon materials and describes the atomic nature of carbon.

In carbon materials except for diamond, the π electrons are valence electrons which are relevant for the transport and other solid state properties. A tight binding calculation for the π electrons is simple but provides important insights for understanding the electronic structure of the π energy levels or bands for graphite and graphite-related materials.

A single-wall carbon nanotube can be described as a graphene sheet rolled into a cylindrical shape so that the structure is one-dimensional with axial symmetry, and in general exhibiting a spiral conformation, called chirality. The chirality, as defined in this chapter, is given by a single vector called the chiral vector. To specify the structure of carbon nanotubes, we define several important vectors, which are derived from the chiral vector.

Using the definition of the structure of carbon nanotubes discussed in Chapter 3, the electronic structure of carbon nanotubes is derived by a simple tight-binding calculation for the π-electrons of carbon atoms. Of special interest is the prediction that the calculated electronic structure of a carbon nanotube can be either metallic or semiconducting, depending on its diameter and chirality. This one-dimensional metal is stable under the so-called Peierls instability. The energy gap for a semiconductor nanotube, which is inversely proportional to its diameters, is directly observed by scanning tunneling microscopy measurements.

This chapter describes synthesis methods for carbon nanotubes, with primary emphasis on single-wall nanotubes. Two relatively efficient methods to synthesize single-wall carbon nanotubes have been identified: laser vaporization and carbon arc synthesis, and both methods depend on the use of catalysts. Other techniques such as vapor growth are also reviewed. Also discussed in this chapter are the synthesis of multi-wall carbon nanotubes, the purification of carbon nanotubes, the insertion of metals into the hollow core of carbon nanotubes, and the doping of carbon nanotubes with alkali metals.

Itinerant electrons in a magnetic field give rise to Landau quantization of the energy bands. In this chapter we show how to calculate the Landau energy bands of carbon nanotubes using the tight-binding method. Quantum confinement of electrons in one-dimensional carbon nanotubes and confinement through application of a magnetic field show interesting phenomena as a function of the chirality of the carbon nanotubes and of the direction and strength of the magnetic field.

Connecting two single-wall carbon nanotubes is an interesting problem, since a semiconductor-metal junction is realized by connecting a semiconductor and a metal carbon nanotube. In this chapter we first show how to connect two carbon nanotubes and then we calculate the electrical conductance of such a junction.

At low temperature a single-wall carbon nanotube is a quantum wire in which the electrons in the wire move without being scattered by scattering centers. We review the difference between classical and quantum transport very briefly in Section 8.1. Then some results on transport experiments in carbon nanotubes are summarized in Section 8.2. Conductance fluctuations as a function of the magnetic field, known as universal conductance fluctuations, are found in carbon nanotubes, and are discussed both experimentally and theoretically.

The phonon dispersion relations of carbon nanotubes can be understood by zone folding the phonon dispersion curves for a single 2D graphene sheet. In Sec. 9.1 and Sec. 9.2, we first explain how to calculate phonon dispersion relations in two-dimensional graphite. Then we discuss phonon dispersion relations for carbon nanotubes in Sec. 9.3. The zone-folding technique is the same as that used in treating the electronic structure of carbon nanotubes, which is discussed in Sec. 4.1.1. We also consider the three-dimensional dynamical matrix, taking the curvature of the nanotubes into account, and obtain results for the phonon dispersion relations.

The Raman-active and infrared-active phonon modes of carbon nanotubes are described on the basis of group theoretical arguments in Sect. 10.1. A review is given in Sect. 10.2 of Raman scattering experiments on purified single-wall nanotubes and arrays of carbon nanotubes, called ropes. To analyze the unique Raman spectra that are observed, results from bond polarization theory are presented in Sect. 10.3. The dependence of the Raman mode frequencies on the nanotube diameter is discussed in Sect. 10.4 and the dependence of the Raman mode intensities on nanotube orientation is discussed in Sect. 10.5.

Since the C=C bond in graphite is the strongest bond in nature, a carbon nanotube is widely regarded as the ultimate fiber with regard to its strength in the direction of the nanotube axis. Furthermore, single wall nanotubes are rather flexible in the direction normal to the nanotube surface. The static elastic properties of carbon nanotubes are discussed in Sect. 11.2. The unusual aspects of the Peierls instability, associated with the distortion which makes an energy gap at the Fermi energy, in carbon nanotubes are discussed in Sect. 11.3. Multi-wall carbon nanotubes have unique properties that do not appear in single wall nanotubes, and these are summarized in Sect. 11.4.

The following sections are included:

• Appendix: Programs for a (n, m) carbon nanotube
  • A-1 Parameters for an (n, m) carbon nanotube
  • A-2 Coordinates for a (n, m) carbon nanotube
  • A-3 Coordinates for several unit cells
  • A-4 Source Codes

• References

• Index