Deep subwavelength electromagnetic transparency through dual metallic gratings with ultranarrow slits

Chunyin Qiu; Sucheng Li; Ruirui Chen; Bo Hou; Feng Li; Zhengyou Liu

doi:10.1103/PhysRevB.87.205129

Deep subwavelength electromagnetic transparency through dual metallic gratings with ultranarrow slits

Chunyin Qiu^*, Sucheng Li, Ruirui Chen, Bo Hou, Feng Li, Zhengyou Liu

^*Corresponding author for this work

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

8 Citations (Scopus)

Abstract

We study the transmission response of microwaves through two identical metallic plates machined with ultranarrow slit arrays. The measured and calculated spectra consistently display a striking transmission peak at wavelength much larger than any characteristic length of the structure (e.g., about 20-fold of the lattice period), which cannot be directly explained by the existing mechanisms. Both the LC-circuit-based microscopic picture and the effective-medium-based macroscopic model are established to capture the essential physics behind such unexpected resonance at the deep subwavelength scale. Prospective applications of this transmission property can be anticipated, considering the merits of compact and excellent immunity to structural imperfections.

Original language	English
Article number	205129
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	87
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevB.87.205129
Publication status	Published - 22 May 2013
Externally published	Yes

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10.1103/PhysRevB.87.205129

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abstract = "We study the transmission response of microwaves through two identical metallic plates machined with ultranarrow slit arrays. The measured and calculated spectra consistently display a striking transmission peak at wavelength much larger than any characteristic length of the structure (e.g., about 20-fold of the lattice period), which cannot be directly explained by the existing mechanisms. Both the LC-circuit-based microscopic picture and the effective-medium-based macroscopic model are established to capture the essential physics behind such unexpected resonance at the deep subwavelength scale. Prospective applications of this transmission property can be anticipated, considering the merits of compact and excellent immunity to structural imperfections.",

author = "Chunyin Qiu and Sucheng Li and Ruirui Chen and Bo Hou and Feng Li and Zhengyou Liu",

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AU - Qiu, Chunyin

AU - Li, Sucheng

AU - Chen, Ruirui

AU - Hou, Bo

AU - Li, Feng

AU - Liu, Zhengyou

PY - 2013/5/22

Y1 - 2013/5/22

N2 - We study the transmission response of microwaves through two identical metallic plates machined with ultranarrow slit arrays. The measured and calculated spectra consistently display a striking transmission peak at wavelength much larger than any characteristic length of the structure (e.g., about 20-fold of the lattice period), which cannot be directly explained by the existing mechanisms. Both the LC-circuit-based microscopic picture and the effective-medium-based macroscopic model are established to capture the essential physics behind such unexpected resonance at the deep subwavelength scale. Prospective applications of this transmission property can be anticipated, considering the merits of compact and excellent immunity to structural imperfections.

AB - We study the transmission response of microwaves through two identical metallic plates machined with ultranarrow slit arrays. The measured and calculated spectra consistently display a striking transmission peak at wavelength much larger than any characteristic length of the structure (e.g., about 20-fold of the lattice period), which cannot be directly explained by the existing mechanisms. Both the LC-circuit-based microscopic picture and the effective-medium-based macroscopic model are established to capture the essential physics behind such unexpected resonance at the deep subwavelength scale. Prospective applications of this transmission property can be anticipated, considering the merits of compact and excellent immunity to structural imperfections.

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JF - Physical Review B - Condensed Matter and Materials Physics

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ER -

Deep subwavelength electromagnetic transparency through dual metallic gratings with ultranarrow slits

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