Analytical Approach of the Nonlinear Surface Plasmon at a Left-Handed Material

Abstract

The surface wave dispersion relations of surface Plasmon at the interface of a left-handed material and a non-linear Kerr medium of arbitrary nonlinearity are derived based on a generalized first integral approach. The normalized power flow is also investigated for various values of frequency. The above study is conducted for both cases: self-focusing (α≺0) and de-focusing (α≻0) nonlinear Kerr coefficient.

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Hamada, M. , El-Astal, A. , Sbiah, M. and Shabat, M. (2015) Analytical Approach of the Nonlinear Surface Plasmon at a Left-Handed Material. Journal of Applied Mathematics and Physics, 3, 673-679. doi: 10.4236/jamp.2015.36080.

1. Introduction

Recently there are great interest and investigation of plasmonics. This is due to the increasing of transmission in layered thin films composed of metals and their experimental applications. Surface Plasmons are charges oscillations occurring at the interface between metal and dielectric layers. Plasmonics concerns with the surface Plasmons and the light interaction with metals.

The interaction of light and surface Plasmon has increased many applications and investigation studies such as developed spectroscopy, high resolution microscopy and sensing, development of light sources and cloaking left-handed materials.

Surface Plasmon excitation concerns with the free electrons oscillation of the interface between metal and dielectric layers leading to the resultant excitation which depends of the optical properties of the two layers and the interface geometry between the two layers. The surface Plasmon excitation is also investigated at simple geometry interface where the left-handed material and the dielectric layers have an interface which is infinite planar [1] [2] .

In our study, a Kerr-nonlinear type dielectric has been investigated where the dielectric function of the dielectric media depends on the electric field intensity. The surface Plasmons dispersion equation at a planar interface between a metal layer and a linear optical layer (where the wave number is k and the angular frequency is ω) can be expressed as the following:

(1)

where c is the speed of light in vacuum and the and are dielectric functions of the dielectric and the metal, respectively, which can depend only on the frequency. Nonlinear dielectric-metal interface cases have also been investigated showing that the surface Plasmon can be excited by both TM and TE waves [3] - [5] . For such cases, the nonlinear surface Plasmon system is leading to the optical bistability, which has been observed recently in the transmission spectrum [6] and in the Goos-Handen shift [7] . It was also found that Equation (1) can be used with the dielectric function of the intensity-dependent medium (nonlinear medium) where can be written as:

(2)

where ε is the linear part and α is a nonlinear dielectric coefficients, which frequency-dependent.

In recent years, there has been an increasing growing interest in new artificial metamaterials. One of the most important reasons is due to the unusual characteristics and behaviors. Some of new interesting application of metamaterial is to use the left handed material or metamaterial in construction optical wave guide sensors [8] [9] .

Instead of a semi-infinite metallic region, we study here the surface Plasmon dispersion relation of a left- handed material (LHM). LHM is a medium with negative permittivity, permeability, and refractive index, which was initially discussed by Veselago [10] in the microwave frequency and could restore the evanescent wave- field components, being thus termed a perfect lens. Nowadays, the efforts have been made to design LHMs for optical frequencies using metallic nanowires [11] . Additionally, it was shown that photonic crystals demonstrate negative refraction under some conditions [12] , thus resembling the most famous feature of LHMs. Many other features of LHM were studied in published papers [13] - [15] . In this work, we also used the correct method (first integral approach) to derive the dispersion relation and present numerical analysis on the limitation of the inexact treatment by comparing its results with the correct theory.

2. Theory

ollowing the theory and approach of a TM-polarized wave which is considered to be propagated at the interface of a Kerr-type medium and a LHM, and by ignoring any loss in both media [16] . So we can easily find out the dispersive relation as follows; For simplicity, we take an isotropic Kerr medium as described in Equation (2), i.e.

. For the case of anisotropic media, it is rather mathematically tedious [13] . In TM waves (Figure 1), we have only y component for H Field, and the electric field in both the nonlinear medium () and the LHM () in general can be written as:

(3)

where c.c. is complex conjugate constant, and the relative phase of the two components and is out of phase. The components of the amplitudes, and in the nonlinear Kerr medium were obtained from the Maxwell equations as following the approach in [16] have the form:

(4)

Figure 1. Geometry of the problem.

The solution of Maxwell Equations (4) in the LHM () which has a dielectric function, the x-com-

ponent electric field amplitude will have the form: where

is selected in the form of the commonly used function for plasmon investigation , and is constructed in an analogous form, i.e.,

(5)

The losses are neglected. Here is an effective plasma frequency that depends upon the geometry of the system, is a resonance frequency and F is a parameter that also depends upon the system structure. For the case of LHM, Equation (4) can be transformed to

(6)

where Dz is the z component of the electric induction vector D. Equation (6) hold in a linear medium with replaced εd by εeff .

The continuity of and across z = 0 then yields;

(7)

with, and is the magnitude of the field.

A standard treatment of the nonlinear region 1 invokes a “first integral” to get at an equation for [17] . Here, the technique is generalized to arbitrary nonlinearity. Differentiating Equation (4) with respect to z and multiplying through by, we get the following equation in region 1, as:

(8)

An integration with respect to z gives

(9)

where C is an integration constant. The key step is to recognize the identity

(10)

The Equation (9) can be rewritten as

(11)

Applying the boundary conditions, , , and must vanish as, then the constant C equals zero. Equation (11) is valid for.

Applying the boundary conditions at Equation (11), then we have new notations as and to give:

(12)

where is the squared magnitude of the electric field at the interface between regions 1 and 2. Requiring this result to be consistent with in Equation (4) gives:

(13)

Furthermore, using Equation (7) together with the relation, the following expressions can be derived as:

(14)

where is given from Equation (2) with.

Now let us apply the above results to derive an explicit and exact dispersion relation for the surface Plasmon at a LHM-Kerr dielectric interface. Substituting Equation (14) into Equation (13), the result can finally be reduced to a quadratic equation in the wave number k which, leading to the following relation:

(15)

Putting the limits or, in the Equation (15) leads to the Equation (1) as expected. By taking the derivative of the Equation (15) to be zero, one can find the surface Plasmon resonance frequency. This is equivalent to find the poles of Equation (15) and by writing Equation (15) in the form:

, one obtains. However, the poles of is to be non-negative. Furthermore, one can show that the additional poles from will be given by and,

which are unacceptable since these will make k = 0 in Equation (15). Thus, we obtain the following implicit expression for to satisfy from the poles of Equation (15):

(16)

Then, the surface plasmon frequency can be solved from Equation (16) to give the following relation:

(17)

This result is compared and contrasted with the one from the inexact approach [18] , namely,

(18)

Note that even in the weak field limit, Equation (17) implies that:

(19)

which contains an extra factor of 1/2 compared within Equation(18).

The power flow in the LHM linear medium is given by:

(20)

And the power flow in the nonlinear medium is written as:

(21)

3. Results and Discussions

It has been noticed that the dispersion curves are obviously changed by the effect of the nonlinearity for both self-focusing () and de-focusing () nonlinear Kerr coefficient, as seen in Figure 2, related to the linear case where α = 0, i.e., in dielectric medium.

In Figure 3, Surface Plasmon frequency is plotted as a function of the nonlinearity (). For, decreases monotonically with while for there is a cutoff values of () above which no

real solution of exists. As can be noticed from Figure 3, the inset shows how the dispersion relation is modified by the field-dependent dielectric constant in a Kerr medium.

The normalized power for different values of frequency is plotted versus the wave vector k in for (in Figure 4) and (in Figure 5). As can be seen in Figure 4 the curves show the behavior of is reciprocal to that of the right-handed material. This behavior is because of the left-handed material layer where the power flow is in the opposite direction. While in Figure 5, where the power flow shows two interesting behaviors, i.e., the non-reciprocal behavior and the bistability behavior. The bistability confirms that some of the power flow is in the positive direction while the other in the negative direction.

4. Conclusion

It is noticed from our above treatment that the dispersion curves are strongly dependent on the intensity of the electric field. The most important conclusions are that for the surface plasmon resonance frequency de-

Figure 2. Dispersion curves for different electric field strength: Eo = 0 (curve 1) and = 9 × 1010 V2/m2, (, curve 2) and (, curve 3).

Figure 3. The surface plasmon frequency versus the field intensity for different value of curve 1, and curve 2.

Figure 4. The normalized power P/Po for different values of frequency: f = 5.1 GHz (curve 1), f = 5.15 GHz (curve 2), and f = 5.19 GHz (curve 3) for.

Figure 5. The normalized power P/Po for different values of frequency: f = 5.11 GHz (curve 1), f = 5.15 GHz (curve 2), and f = 5.17 GHz (curve 3) for.

creases monotonically with whereas for, there is a cutoff value. It has been shown that the reversed power flow is due to the LHM material which is acting as a mirror for, but for both re-

versal and bistability cases have been clearly observed. The two interesting behaviors could lead to new design of future application in Optoelectronic-Microwave technology.

NOTES

*Corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.

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