Anderson Localization of Classical Waves in Weakly Scattering Metamaterials

TL;DR

This paper investigates how classical waves propagate and localize in one-dimensional disordered layered structures, revealing differences between mixed left- and right-handed materials and homogeneous stacks, with analytical and numerical insights.

Contribution

The study develops an analytical approach to calculate transmission lengths in weakly scattering layered structures, highlighting differences in localization behavior between mixed and homogeneous stacks.

Findings

Transmission length exhibits quadratic wavelength dependence in localized regime.

Mixed stacks with refractive-index disorder suppress Anderson localization at long wavelengths.

Theoretical predictions align well with numerical simulations.

Abstract

We study the propagation and localization of classical waves in one-dimensional disordered structures composed of alternating layers of left- and right-handed materials (mixed stacks) and compare them to the structures composed of different layers of the same material (homogeneous stacks). For weakly scattering layers, we have developed an effective analytical approach and have calculated the transmission length within a wide region of the input parameters. When both refractive index and layer thickness of a mixed stack are random, the transmission length in the long-wave range of the localized regime exhibits a quadratic power wavelength dependence with the coefficients different for mixed and homogeneous stacks. Moreover, the transmission length of a mixed stack differs from reciprocal of the Lyapunov exponent of the corresponding infinite stack. In both the ballistic regime of a mixed stack and in the near long-wave region of a homogeneous stack, the transmission length of a realization is a strongly fluctuating quantity. In the far long-wave part of the ballistic region, the homogeneous stack becomes effectively uniform and the transmission length fluctuations are weaker. The crossover region from the localization to the ballistic regime is relatively narrow for both mixed and homogeneous stacks. In mixed stacks with only refractive-index disorder, Anderson localization at long wavelengths is substantially suppressed, with the localization length growing with the wavelength much faster than for homogeneous stacks. The crossover region becomes essentially wider and transmission resonances appear only in much longer stacks. All theoretical predictions are in an excellent agreement with the results of numerical simulations.