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The propagation of classical waves in one-dimensional random media is examined in presence of short-range correla
tion in disorder. A classical analogous of the Kronig-Penney model is proposed by means a chain of repeated sub-sys
tems, each of them constituted by a mass connected to a rigid foundation by a spring. The masses are related to each other by a string submitted to uniform tension. The nature of the modes is investigated by using different transfer matrix formalisms. It is shown that in presence of short-range correlation in the medium which corresponds to the RD model- the localization-delocalization transition occurs at a resonance frequency ** **modes in contradiction with the general conclusion of the lo
calization phenomenon in one-dimensional systems with correlated disorder.

More than a half century ago, Anderson [

- the existence of a critical dimension such for, all the electronic states are localized.

- the transition from localized to extended states occurs only for.

- the transition is continuous.

Nowadays, these conclusions are of universal validity and supported by strong experimental evidences (for a review see [3-5]). Indeed, the results for the one-dimensional disordered case were anticipated earlier from the Mott and Twose’s theorem [

Physically, the destructive quantum interferences appear to be the fundamental mechanism of localization induced by disorder. Thus it becomes cleaver to expect similar observation of the localization effects in other wave propagation phenomena [for a review see Ref. 7], namely classical wave equations [

However, almost of this aspect holds only for uncorrelated disorder. In this context over the last couple of decades, convincing arguments revealed that short range correlations in disorder may have spectacular and unexpected effects [

In this domain, originally introduced by Dunlap et al. [

Although a great interest has been given to the electronic case, very few has been done for the classical analog. Moreover periodic systems are known to have some bearing in modeling of engineering structures. In the following paper, a classical analog of the Anderson localization model is examined. In particular, a classical wave propagation in random media is investigated through a structure displaying a one-dimensional character. The conditions to breakdown the localization phenomenon and to restore the propagations of wave are suggested. The opportunity to control this feature opens new and relevant perspectives for technological purposes.

In this context, the purpose of the present paper is to examine the interplay between the effects of topological disorder and short range order on the propagation of classical waves by means of an analytical model for the case of a quasi-one-dimensional string loaded by N massspring systems has introduced by Richoux et al. [

In the following paper, a classical analog of the Anderson localization model is examined A quasi-one-dimensional string is loaded^{ }by N masses, each one fixed to a spring. Disorder^{ }is introduced onto the system by considering masses, springs and/or lattice^{ }spacing as random variables. The wave propagation^{ }is formulated in terms of the transfer matrix. The transmission coefficient and the Lyapunov^{ }exponent is computed for different situations, yielding the frequency spectrum^{ }and the localization length. Both analytical results and numerical simulations have been performed^{ }for the ordered as well as disordered cases. The conditions to breakdown the localization phenomenon and to restore the propagations of wave are suggested.

In the following, we consider treat the transverse vibrations of an infinite tight string having an homogeneous density submitted to a uniform tension and connected to a grounding rigid foundation. The string is loaded by elementary cells constituted by a mass-spring system along. The n-th cell is characterized by two physical parameters: the mass and the linear stiffness constant. The masses are located at the lattice point along the -axis between two fixed ends at and and the lattice spacing is denoted by (see

We focus our attention to the propagation of transverse wave in the vertical plane. The wave amplitude y at the longitudinal coordinate x is solution of the general wave propagation equation in space:

with

and (2)

Here K and stands for the wave vector and the wave (or sound) velocity through the whole system respectively. w is the fundamental frequency to be determined.

The quantity associated to each delta peak corresponds to the vibration mode defined by [

where:

The term is the free frequency of the n^{th} cell while the parameter may be understood as an effective delta peak strength. The inverse has the physical meaning of a characteristic length translating the bearing of the associated string.

The wave Equation (1) represents a perfect analogy with the electronic Kronig-Penney model, namely:

Randomness may be introduced in different ways: disorder in mass and/or stiffness, referred to the cellular disorder, and/or disorder in position through the symbol S, i.e. the so-called topological disorder. Moreover as reported by Maynard [

For the n-th region within the interval

, the solution of Equation (1) is a superposition of forward and backward scattering waves:

where are the amplitude coefficients.

The transfer matrix relating the amplitudes between two successive cells is defined by:

For convenience, we introduce the reflection the transmission amplitudes and of the system, assuming that the incident amplitude as unity. Following this description, obeys to the boundary conditions:

The amplitudes and through the initial and final amplitudes can be linearly expressed using boundary conditions in a close expression giving the total transfer matrix of the whole system, such as:

with

Then, the transmission coefficient, describing the wave propagation, may be numerically computed via the relation:

The knowledge of enables one to determine the nature of the propagating modes by means the normalized Lyapunov exponent given by the ratio [ ]:

x being the localization length.

For the particular situation where all the strength

vanish, i.e. all the frequencies are identical

and the existence of a, a spectacular phenomenon occurs. Equation (1) reduces to:

which describes the free wave propagation. The transmission coefficient reaches it maximum value, independently from the system length. Consequently, the wave propagates freely through the string leading to the so-called ballistic regime.

A proper understanding of the effect of the disorder on the band structures of the modes of vibration requires the knowledge of the ordered limit case. Towards this end it is convenient to take advantage of the d-function limit, the wave propagation equation may be handled within the framework of the Poincaré map representation relating two successive lattice points. According to Bellissard et al. [

with:

where

yields the frequency spectrum [

The condition determining the bands of the allowed and forbidden frequencies is then:

Setting, it simplifies to:

whose solutions are:

For the n-th allowed bands, the frequencies obey to:

Since we are considering the ordered limit, the parameters are identical to the same value l.

In Equation (19), the term measures the width of a forbidden band Δω. It may be written as:

Moreover if the upper limit of the band is well determined, the limit of lower limit frequency appears to be challenging from the physical point of view by treating analytically the amplitude of the wave and determining the band edge as well. Towards this end let us start with the relation:

For convenience, setting:

and

it reduces to in the limit:

or in the continuum limit,

being solution of the equation:

As usual, for propagating wave of type

:

The sign of the variable enables one to discriminate the nature of the propagating wave; if, ω belongs to an allowed band and if to a forbidden one. Thus the condition determines the lower band edge since we are concerned by the limit of low frequencies, namely:

Obviously we have retained only the positive solution, i.e:

Let us consider now a set of two unit cells separated by a distance d and distributed at random along the x axis. Thus Equation (1) becomes:

In the following topological disorder, all the cells are identical, i.e. constituted by the same mass m and the same spring with stiffness k. Thus all the variables l_{n} are equal:

The wave equation Equation (34) may be solved for a one dimer cell located at and:

for (36-c)

Matching the wave amplitudes at x_{n} = 0 and yields:

Setting, one may reformulate the complex through the exponential representation via:

with the boundary conditions:

and (39)

The coefficient A may written as:

Defining:

the transmission coefficient is then:

and for all the acoustical wave having wave vector where:

Here the delocalization condition may formulated in term of the coefficient A by;

or equivalently:

Surprisingly, the first equation is the same as the initial equation defining the frequency spectrum.

This result is quite different from the condition obtained by Hilke et al. [

It could also be written by using:

Physically, as long as the condition (11) is fulfilled, the wave does not feel the random character of the media since the distance between a double sequence is a multiple of its wavelength. This in turn is only a proper characteristic of the dimer cell as usual.

In order to appreciate more deeply the nature of such waves, a proper understanding requires the knowledge on the behavior of the divergence of the localization length. Towards this end, let us consider a zero-order approximation to the overall transmission coefficient of the random media. Namely, we compute the transmission coefficient of each double sequence and just multiply them together [

Here denotes the transmitted amplitude corresponding to an incident amplitude. stands for the transmission coefficient of each double sequence. According to [

Substitution of Equation (12) in Equation (13) yields:

The coefficient in the limit of K close to K_{n} may be expanded to a second order approximation:

where the parameters a and m are given by:

with:

Thus, the localization length becomes:

In the limit of vanishing, i.e. close to an “extended” state, the localization length scales as:

The critical exponent for the localization length is then. To our knowledge such exponent is found analytically for the first time for the case of the propagation of classical wave. A similar result has been found for the vibrational modes in harmonic chains of N masses related by springs with correlated disorder [

Here we consider a binary and correlated of the disorder, i.e. one which the linear stiffness constant and mass take only two values, { and } and { and } with the additional constraint that the and values appear only in pairs of neighboring cells of the chain (dimer) but distributed at random locations along the chain. To predict the origin of possible resonance frequency, we improve from analytical consideration that yields the frequency in terms of the mass and the linear stiffness constant. As indicating Equation (13), there are four different kind of transfer matrix and random chain Typically the transfer matrices associated to the host and dimer unit cells are defined by:

In particular, at the two formulas for and crossover, nameely. Hence, the resulting matrix elements become identical and consequently, and commute. Physically, the incident propagating mode becomes insensitive to the difference between the host and impurity cells since they act in the same local diffusive way. The propagating media is felt as an ordered lattice, with identical effective delta peak strength. The frequency referred as the commuting frequency, can be determined analytically, from the condition:

i.e.

At this commuting resonance frequency, the two indiscernible unit cells present similar properties leading to deterministic features. This finding appears in agreement with the case of electron in superlattices in presence of dimer as reported by Gomez et al. [

This typical feature is completely preserved in the corresponding uncorrelated disorder since there is no difference between the host and impurity unit cells as originally reported by Ishii [

Finally, an interesting feature takes place on the commuting resonance with the presence of periodic amplitude at the commuting frequency, justifying the extended Bloch diffusive character of the corresponding propagating resonant mode. Moreover combined effects occur near this particular resonance since the vibration mode is sensitive to the unit cells [A] and [B]. Such disorder localizes the Bloch-like extended modes within a mini band around, giving rise to a soft transition.

The propagation of classical waves in random media has been studied by using an analogous with the electronic disordered Kronig-Penney model to observe the phenomenological aspects of the Anderson localization. We have examined the wave propagation through a system constituted by a quasi-one-dimensional string loaded by N mass-spring systems. In the light of analytical results, relevant conclusions have been obtained.

The presence of short range correlation in disorder lead to the existence of delocalized modes of vibration well defined at well defined frequencies within the band spectrum.

Moreover the behavior of the localization length around these frequencies exhibits a divergence with a critical exponent which has been found equal to 2. The same value has been obtained previously by Datta et al. [

In this description, two particular frequencies characterize the corresponding the ordered case: the fundamental frequency vanishes the Kronig-Penney analytical equation, i.e. while the free frequency settles down the ballistic regime i.e. Singular behavior happens around the free frequency since the spatial extent length diverges, i.e.

pointing out the Bloch-like modes.

Dimers can be constructed with a new interesting way that preserves the ballistic regime even in presence of pairing configuration. The Bloch-like extended states are restored in controversies with the general belief that no periodic wave function exist in the well known random dimer model. Another resonance appears at the commuting frequency. This describes an additional delocalization process since its corresponding extended eigenstates are fundamentally different.

To conclude, we have reported analytical results describing the random dimer effect in a classical mechanic situation. At this stage, this model presents the main advantage to be checked experimentally within a rather simple method [