Interplay between evanescence and disorder in deep subwavelength photonic structures

Hanan Herzig Sheinfux; Ido Kaminer; Azriel Z. Genack; Mordechai Segev

doi:10.1038/ncomms12927

Interplay between evanescence and disorder in deep subwavelength photonic structures

Hanan Herzig Sheinfux, Ido Kaminer, Azriel Z. Genack, Mordechai Segev

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Deep subwavelength features are expected to have minimal impact on wave transport. Here we show that in contrast to this common understanding, disorder can have a dramatic effect in a one-dimensional disordered optical system with spatial features a thousand times smaller than the wavelength. We examine a unique regime of Anderson localization where the localization length is shown to scale linearly with the wavelength instead of diverging, because of the role of evanescent waves. In addition, we demonstrate an unusual order of magnitude enhancement of transmission induced due to localization. These results are described for electromagnetic waves, but are directly relevant to other wave systems such as electrons in multi-quantum-well structures.

Original language	English
Article number	12927
Journal	Nature Communications
Volume	7
DOIs	https://doi.org/10.1038/ncomms12927
State	Published - 6 Oct 2016

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General
General Physics and Astronomy

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10.1038/ncomms12927

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title = "Interplay between evanescence and disorder in deep subwavelength photonic structures",

abstract = "Deep subwavelength features are expected to have minimal impact on wave transport. Here we show that in contrast to this common understanding, disorder can have a dramatic effect in a one-dimensional disordered optical system with spatial features a thousand times smaller than the wavelength. We examine a unique regime of Anderson localization where the localization length is shown to scale linearly with the wavelength instead of diverging, because of the role of evanescent waves. In addition, we demonstrate an unusual order of magnitude enhancement of transmission induced due to localization. These results are described for electromagnetic waves, but are directly relevant to other wave systems such as electrons in multi-quantum-well structures.",

author = "\{Herzig Sheinfux\}, Hanan and Ido Kaminer and Genack, \{Azriel Z.\} and Mordechai Segev",

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AU - Herzig Sheinfux, Hanan

AU - Kaminer, Ido

AU - Genack, Azriel Z.

AU - Segev, Mordechai

PY - 2016/10/6

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N2 - Deep subwavelength features are expected to have minimal impact on wave transport. Here we show that in contrast to this common understanding, disorder can have a dramatic effect in a one-dimensional disordered optical system with spatial features a thousand times smaller than the wavelength. We examine a unique regime of Anderson localization where the localization length is shown to scale linearly with the wavelength instead of diverging, because of the role of evanescent waves. In addition, we demonstrate an unusual order of magnitude enhancement of transmission induced due to localization. These results are described for electromagnetic waves, but are directly relevant to other wave systems such as electrons in multi-quantum-well structures.

AB - Deep subwavelength features are expected to have minimal impact on wave transport. Here we show that in contrast to this common understanding, disorder can have a dramatic effect in a one-dimensional disordered optical system with spatial features a thousand times smaller than the wavelength. We examine a unique regime of Anderson localization where the localization length is shown to scale linearly with the wavelength instead of diverging, because of the role of evanescent waves. In addition, we demonstrate an unusual order of magnitude enhancement of transmission induced due to localization. These results are described for electromagnetic waves, but are directly relevant to other wave systems such as electrons in multi-quantum-well structures.

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VL - 7

JO - Nature Communications

JF - Nature Communications

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ER -

Interplay between evanescence and disorder in deep subwavelength photonic structures

Abstract

All Science Journal Classification (ASJC) codes

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