Abstract

Surface plasmons (SPs) carry electromagnetic energy in the form of collective oscillation of electrons at metal surface and commonly demonstrate two important features: strong lateral confinement and short propagation lengths. In this work we have investigated the trade-off relationship existing between propagation length and lateral confinement of SP fields in a hyperbolic metamaterial system, and explored loosening of lateral confinement as a means of increasing propagation length. By performing finite-difference time-domain analysis of Ag/SiO2 thin-film stacked structure we demonstrate long range (~ 100 mm) propagation of SPs at 1.3 µm wavelength. In designing low-loss loosely-bound SPs, our approach is to maximally deplete electric fields (both tangential and normal components to the interface) inside metal layers and to support SP fields primarily in the dielectric layers part of metamaterial. Such highly-localized field distributions are attained in a hyperbolic metamaterial structure, whose dielectric tensor is designed to be highly anisotropic, that is, low-loss dielectric (Re(ε) > 0; Im(ε) ~ 0) along the transverse direction (i.e., normal to the interface) and metallic (large negative Re(ε)) along the longitudinal direction, and by closely matching external dielectric to the normal component of metamaterial’s dielectric tensor. Suppressing the tangential component of electric field is shown to naturally result in weakly-confined SPs with penetration depths in the range of 3–10 µm. An effective-medium approximation method is used in designing the metamaterial waveguide structure, and we have tested its validity in applying to a minimally structured core-layer case (i.e., composed of one or two metal layers). Low-loss loosely-bound SPs may find alternative applications in far-field evanescent-wave sensing and optics.

Highlights

  • Supporting a surface-bound wave at metal/dielectric interface, plasmonic metals enable novel phenomena [1,2,3,4,5]

  • In this work we have investigated the trade-off relationship existing between lateral confinement and propagation length of Surface plasmons (SPs) supported in a hyperbolic metamaterial system and explored the opposite regime of SP phenomena, i.e., the case of loose confinement and long propagation length

  • 7 Conclusions We have investigated the trade-off relationship existing between propagation length and lateral confinement of surface-bound waves in a hyperbolic metamaterial system, and explored loosening of lateral confinement as a means of increasing propagation length

Read more

Summary

Introduction

Supporting a surface-bound wave at metal/dielectric interface, plasmonic metals enable novel phenomena (e.g., negative refraction, field concentration and cloaking) [1,2,3,4,5]. In order to support low-loss loosely-bound SPs the metamaterial’s dielectric tensor is required to satisfy the following conditions: tangential component should be metallic (Re(ɛm,t) < 0) for evanescent confinement in both sides (γd,n, γm,n > 0); normal component should be lowloss dielectric ( Re(εn) > 0; Im(εn) ∼ 0) for long propagation lengths ( Im(kt ) ∼ 0) ; tangential E-field should be suppressed (Et ∼ 0) for loose confinement (γn ∼ 0). These requirements can be met in a highly anisotropic hyperbolic metamaterial system. From Eq (7), lateral decay constant (γn) becomes zero (i.e., loosely confined) as ɛd/ɛm,n approaches 1

Metallodielectric thin‐film stack and effective medium approximation
Wave‐vector diagram for hyperbolic metamaterial
Field distributions in multilayer‐stacked hyberbolic metamaterial
Conclusions

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.