Litcius/Paper detail

General Impedance Matching via Doped Epsilon-Near-Zero Media

Ziheng Zhou, Yue Li, Ehsan Nahvi, Hao Li, Yijing He, Iñigo Liberal, Nader Engheta

2020Physical Review Applied47 citationsDOI

Abstract

The emerging technique of photonic doping endows epsilon-near-zero (ENZ) media with a broadly tunable effective magnetic permeability. Here, we theoretically and experimentally demonstrate that a finite-size doped ENZ region counterintuitively behaves as a lumped circuit element, modeled as a controllable series reactance. Based on this concept, a general matching network is constructed to match a load with arbitrary complex impedance, while, interestingly, its operating bandwidth can also be modified by fine-tuning the dopants' properties. To demonstrate the universality of the concept, different kinds of loads are matched, including microwave circuits, antennas, and absorbing particles. Since this general impedance matching technique is not limited to a specific type of load, nor a specific geometry, and can be readily transplanted from microwave to optical regimes, the proposed methodology facilitates impedance matching for maximum usage of power in quite general scenarios, and thus, exhibits promising potential for broad applications.

Topics & Concepts

Impedance matchingReactanceMicrowaveElectrical impedanceBandwidth (computing)Materials scienceDopingMatching (statistics)Finite element methodHomogenization (climate)OptoelectronicsElectronic engineeringPhysicsComputer scienceTelecommunicationsMathematicsEngineeringVoltageBiodiversityBiologyThermodynamicsEcologyStatisticsQuantum mechanicsMetamaterials and Metasurfaces ApplicationsPlasmonic and Surface Plasmon ResearchPhotonic Crystals and Applications