High-Frequency Electric Field Induced Nonlinear Electron Transport in Chiral Carbon Nanotubes

doi:10.4236/wjcmp.2015.54030

World Journal of Condensed Matter Physics
Vol.05 No.04(2015), Article ID:61400,7 pages
10.4236/wjcmp.2015.54030

Sulemana S. Abukari¹, Samuel Y. Mensah¹, Musah Rabiu², Kofi W. Adu^3,4*, Natalia G. Mensah⁵, Anthony Twum¹, Alfred Owusu¹, Kwadwo A. Dompreh¹, Patrick Mensah-Amoah¹, Matthew Amekpewu²

●How to Cite this Article

¹Department of Physics, Laser and Fibre Optics Centre, University of Cape Coast, Cape Coast, Ghana

²Department of Applied Physics, University for Development Studies, Navorongo, Ghana

³Department of Physics, The Pennsylvania State University-Altoona, Altoona, USA

⁴Materials Research Institute, The Pennsylvania State University, University Park, USA

⁵Department of Mathematics, University of Cape Coast, Cape Coast, Ghana

This work is licensed under the Creative Commons Attribution International License (CC BY).

http://creativecommons.org/licenses/by/4.0/

Received 5 November 2014; accepted 21 November 2015; published 24 November 2015

ABSTRACT

We investigate theoretically the high frequency complex conductivity in carbon nanotubes that are stimulated axially by a strong inhomogeneous electric field of the form. Using the kinetic approach based on Boltzmann’s transport equation with constant relaxation time approximation and the energy spectrum of the electron in the tight-binding approximation, together with Bhatnagar-Gross-Krook collision integral, we predict high-frequency nonlinear effects along the axial and the circumferential directions of the carbon nanotubes that may be useful for the generation of high frequency radiation in the carbon nanotubes.

Keywords:

Carbon Nanotubes, High Frequency Electric Field, Electric Current Density, Complex Conductivity

1. Introduction

Carbon nanotube (CNT) is an allotrope of carbon with nanometers size diameter and an aspect ratio as high as ~10⁷. In 1952, images of 50 nanometer diameter tubes of carbon were reported by Radushkevich and Lukyanovich [1] . Using the vapor-growth technique, Orberlin and coworkers [2] reported observation of hollow carbon fibers of nanometer size diameters. Other reports also published similar observation of tubular carbon nanostructures [3] . However, the credit for the discovery of CNTs goes to S. Iijima [4] . This one-atom thick sheet of graphene rolled up into a seamless cylinder has since attracted a great deal of interest, mainly due to their unique thermal, chemical and physical properties [5] [6] . These properties depend on the fundamental indices (n,m) of the CNTs. The indices (n,m) determine the diameter and the chiral angle of the CNTs. As n and m vary, the conduction ranges from metallic to semiconducting [7] , with an inverse diameter dependent band gap of ≤ 1 eV [7] .

The electron transport properties of the CNTs continue to be the subject of intense research. CNTs have been shown to exhibit ballistic transport [8] -[10] , Coulomb-blockade [11] -[13] , Luttinger Liquid [14] [15] and superconductivity [16] [17] . The unique architectural, structural and physicochemical properties have made CNT a promising candidate for application in new generation of nanoelectronics [18] -[21] , sensors [22] [23] , electrochemical capacitors [24] -[26] , Li-ion batteries [27] -[29] and terahertz (THz) generation and amplification [30] - [34] , just to mention a few. Furthermore, negative differential conductivity properties of CNTs have been reported [6] [35] [36] , while phenomena like rectification of electromagnetic waves, domain suppression in negative differential conductivity region, high-frequency (hf) conductivity, high order harmonic generation and many others have also been considered [37] -[40] .

In this work, we report on a high frequency (hf) complex conductivity in CNTs using the standard linear electrodynamical approach [15] -[17] . We use the kinetic approach based on Boltzmann’s transport equation with constant relaxation time approximation and the energy spectrum of the electron in the tight-binding approximation, together with Bhatnagar-Gross-Krook (BGK) collision integral. This approach permits adequate allowance for the particle-number conservation law for scattering inhomogeneous field as well as the influence on the electron spectrum by both resonance effects due to Bloch oscillations of the electrons and by the effects connected with the carrier drift and diffusion under conditions of strong spatial dispersions.

2. Theory

Using the simple model of the tight-binding approximation, we describe the energy spectrum of the CNTs as [39]

, (1)

where the indices s and z correspond to the circumferential and axial directions, respectively. is the energy of an outer-shell electron in an isolated carbon atom, D_z and D_s are the real overlapping integrals for jumps along the respective coordinates, and are the components of momentum tangential to the base helix and along the nanotube axis, respectively. is Planck’s constant, and d_z and d_s are the distances along the CNT axis and helix, respectively.

We consider the Boltzmann transport equation with constant relaxation time together with Bhatnagar-Gross- Krook (BGK), which account for the spatial effects due to the conservation of the number of scattered particles [41] [42] ,

. (2)

The distribution function and the equilibrium distribution function are periodic and can be written in Fourier series as in Equations (3) and (4), respectively.

(3)

and

(4)

where n_o is the equilibrium carrier density, n(x) is the electron density at position x, v(p) is the electron velocity, p

is the electron dynamical momentum, t is elapsed time, τ is the electron relaxation time, e is the electron charge, E(t) is the external electric field, is the Boltzmann’s constant and T is the temperature. The collision integral is taken in the relaxation time τ approximation and further assumed to be constant. is the factor by which the Fourier transform of the nonequilibrium distribution function differs from its equilibrium distribution counterpart. I_m (I_n) is the modified Bessel function of the order m(n) and I_o is the modified Bessel function of the zeroth order.

In addition to Equation (2), we employ the Poisson equation that will allow for continuous current, i.e., , where ε is the lattice dielectric constant. For a constant homogeneous electric field, the electron distribution for both the tubular axis z and the base helix s is expressed as:

(5)

where , and n is the scattering frequency. We use the conditions of inhomoge-

neous perturbations with frequency w and wave-vector k of the following form:, and, and solving the linearized kinetic equation (Equa-

tion (2)), we obtained [41] -[43] ,

(6)

where, is the normalized wave number of the perturbations, and (i = s, z) is the dimensionless quasimomentum. The electron flux along the tubular axis (F_z) and the base helix (F_s) can be expressed as [39] [40] ,

(7a)

(7b)

where the integration is done over the first Brillouin zone. Using Equation (7) together with the solution of Equation (6) we obtain the following expressions:

(8a)

(8b)

Defining the axial and the circumferential components of the current density as and, respectively [39] [40] , where q_h is the chiral angle of the CNTs, the current densities are expressed as [43] [44] ,

(9a)

and

. (9b)

Using and linearizing the result with for, the expressions for the complex conductivities along the axial and the circumferential directions are expressed, respectively, as:

(10a)

and

(10b)

3. Results and Discussions

Using the solution to the Boltzmann’s transport equation with constant relaxation time together with Bhatnagar- Gross-Krook collision integral, we obtained the expressions for the complex conductivities along the axial and circumferential directions of the CNTs. We analyzed the effects of the high frequency electric field by considering the dependence of the complex conductivity on the dimensionless frequency (Equation (10)) . Shown in Figure 1 are the plots of the complex conductivities along the axial [Figure 1(a)] and the

(a)(b)

Figure 1. The real (red solid curve) and the imaginary (blue solid curve) parts of the normalized complex conductivity s/s_o as a function of normalized frequency w/W along the circumferential (top) and axial (bottom) directions of CNT.

circumferential [Figure 1(b)] directions. The red and the blue curves represent the real and the imaginary parts of the conductivity, respectively. The complex conductivity along both directions exhibits similar characteristics. The dimensionless complex conductivity depends strongly and nonlinearly on the normalized frequency . It can be seen from the plots that the real part of the complex conductivity becomes more negative with increasing the frequency until a resonance minimum occurs just before the Bloch frequency W . This negative-conductivity resonance near the Bloch frequency makes the CNT a potential active medium for Bloch oscillations without domain instabilities induced by negative dc conductivity.

4. Conclusion

In summary, we have obtained the nonlinear high frequency conductivity in CNTs that are stimulated axial with a strong inhomogeneous electric field by using the Boltzmann’s equation with constant relaxation time approximation together with the Bhatnagar-Gross-Krook collision integral. We predict this high-frequency nonlinear effect along the axial and the circumferential directions of the carbon nanotubes may be useful for the generation of a high frequency radiation in the carbon nanotubes.

Cite this paper

Sulemana S.Abukari,Samuel Y.Mensah,MusahRabiu,Kofi W.Adu,11,Natalia G.Mensah,AnthonyTwum,AlfredOwusu,Kwadwo A.Dompreh,PatrickMensah-Amoah,MatthewAmekpewu, (2015) High-Frequency Electric Field Induced Nonlinear Electron Transport in Chiral Carbon Nanotubes. World Journal of Condensed Matter Physics,05,294-300. doi: 10.4236/wjcmp.2015.54030

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NOTES

^*Corresponding author.

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