High transmission through high index metamaterial

Slides:

Advertisements

Similar presentations

ENE 428 Microwave Engineering

Advertisements

Study of propagative and radiative behavior of printed dielectric structures using the finite difference time domain method (FDTD) Università “La Sapienza”,

Lecture 8: Reflection and Transmission of Waves

Shaping the color Optical property of photonic crystals Shine.

FRACTAL MEMBRANES Wen, Zhou, et al.. Applied Physics Letters Volume 82, No. 7, 17 February 2003 Abstract: Reflectivity of Planar Metallic Fractal Patterns.

TechWatch 2004: Miniaturized antennas based on negative permittivity materials—Lucent Technologies Metamaterial scanning lens antenna systems and methods—The.

Module 1-1 Continued Nature and Properties of Light.

Optics 1. 2 The electromagnetic spectrum Visible light make up only a small part of the entire spectrum of electromagnetic waves. Unlike sound waves and.

8. Wave Reflection & Transmission

1. 2 The present review covers the scattering of plane electromagnetic waves on spherical objects The results shown here might be extended to any arbitrary.

Surface polaritons in layered semiconductor structures M. Duracz, A. Rusina. Saint-Petersburg State Polytechnical University, Saint-Petersburg, Russia.

Phy 212: General Physics II Chapter 35: Interference Lecture Notes.

Photonic Ceramics EBB 443-Technical Ceramics Dr. Sabar D. Hutagalung School of Materials and Mineral Resources Engineering Universiti Sains Malaysia.

Chapter 33 Electromagnetic Waves

Electromagnetic Wave Theory

Week 10 – More E&M theory, attenuation, color.

+ Lens Effect with Photonic Crystals Student “#3” ECEN 5616 Final Project Presentation

Reflection and Refraction of Plane Waves

Reflection and Transmission of Plane Waves

The Hong Kong Polytechnic University Optics II----by Dr.H.Huang, Department of Applied Physics1 Light Waves Nature of Light: Light can be viewed as both.

Acceleration: Sinusoidal E/M field Sinusoidal Electromagnetic Radiation.

1 EEE 498/598 Overview of Electrical Engineering Lecture 11: Electromagnetic Power Flow; Reflection And Transmission Of Normally and Obliquely Incident.

Optics of a single Homogeneous and Isotropic Layer

Modeling Plasmonic Effects in the Nanoscale Brendan McNamara, Andrei Nemilentsau and Slava V. Rotkin Department of Physics, Lehigh University Methodology.

RS ENE 428 Microwave Engineering Lecture 3 Polarization, Reflection and Transmission at normal incidence 1.

WAVE Basics Chapters 15.

Periodic Boundary Conditions in Comsol

1 Electromagnetic waves: Multiple beam Interference Friday November 8, 2002.

The Fundamental Physics of Directive Beaming at Microwave and Optical Frequencies in Terms of Leaky Waves Saman Kabiri, Master’s Student Dept. of Electrical.

Prof. D. R. Wilton Notes 18 Reflection and Transmission of Plane Waves Reflection and Transmission of Plane Waves ECE 3317 [Chapter 4]

RS ENE 428 Microwave Engineering Lecture 3 Polarization, Reflection and Transmission at normal incidence 1.

EMLAB 1 Examples of One ‐ Dimensional FDTD. EMLAB 2 Typical FDTD Grid Layout.

1 METAMATERIALS Metamaterials are artificial engineered composite structures that can be designed to exhibit specific electromagnetic properties not observed.

5 장 Dielectrics and Insulators. Preface ‘ Ceramic dielectrics and insulators ’ is a wide-ranging and complex topic embracing many types of ceramic, physical.

Understanding the Electromagnetic Characteristics of Real Metamaterials via Rigorous Field Simulation Raj Mittra Electromagnetic Communication Laboratory.

Enhancing One‐Dimensional FDTD

December 7, 2011 Acoustic Cloaking: Manipulating Sound with Artificial Materials Bogdan Popa, Lucian Zigoneanu, Steven Cummer Electrical and Computer Engineering.

1 EE 543 Theory and Principles of Remote Sensing Reflection and Refraction from a Planar Interface.

Speed of light Galileo – “Its fast”

02/20/2015PHY 712 Spring Lecture 161 PHY 712 Electrodynamics 9-9:50 AM Olin 103 Plan for Lecture 16: Read Chapter 7 1.Plane polarized electromagnetic.

Physics 213 General Physics Lecture Last Meeting: Electromagnetic Waves, Maxwell Equations Today: Reflection and Refraction of Light.

Remcom Inc. 315 S. Allen St., Suite 416  State College, PA  USA Tel:  Fax:   ©

Foundation year General Physics PHYS 101 Chapter 4 : Light and Optics Instructor: Sujood Alazzam 2015/

High performance optical absorber based on a plasmonic metamaterial 岑剡.

Tunably controlling waveguide behaviors are always desirable for various kinds of applications. In this work, we theoretically propose.

All-Dielectric Metamaterials: A Platform for Strong Light-Matter Interactions Jianfa Zhang* （College of Optoelectronic Science and Engineering, National.

Physical concept Conclusions A gradient-index meta-surface is the very bridge to link PWs and SWs. Besides obvious interest in fundamental science, our.

Date of download: 9/17/2016 Copyright © 2016 SPIE. All rights reserved. The implementation of the angular spectrum of plane waves method in the finite.

Acoustic Metamaterials and the Dynamic Mass Density Ping Sheng Department of Physics, HKUST IPAM Workshop on Metamaterials

17. Electromagnetic waves

UPB / ETTI O.DROSU Electrical Engineering 2

DALHM MEETING July 29-30, 2004 FORTH Heraklion, Crete, GREECE

Electromagnetic Waves

FORTH - Modelling Issues addressed

ELEC 401 MICROWAVE ELECTRONICS Lecture 3

THEORIES OF LIGHT Is light a wave or a stream of particles?

ELEC 401 MICROWAVE ELECTRONICS Lecture 3

Anomalous high transmission through opaque metamaterials

Introduction to Spectroscopic Methods

Optical-Null Transformation Medias: Realizations and Applications

Lecture 12 Optical Properties Md Arafat Hossain Outlines.

Notes 18 ECE 3317 Applied Electromagnetic Waves Prof. David R. Jackson

Department of Physics, Fudan University, Shanghai , China

ENE 428 Microwave Engineering

Antenna Theory Chapter.4.7.4~4.8.1 Antennas

Samuel Gomez Mentor: Sirak M. Mekonen

Resonance properties of metallic ring systems: A rigorous approach

Tailor the Angular Dispersion of Metasurfaces

Planar gradient meta-surface to focus EM waves in reflection geometry

Xi Bin, Xu Hao, Xiao Shiyi, Hao Jiaming and Zhou Lei

Presentation transcript:

High transmission through high index metamaterial Zhengyong Song, and Lei Zhou Surface Physics Laboratory (State Key Laboratory) and Department of Physics, Fudan University, Shanghai 200433, China Abstract: The metamaterial consisting of thin layers of alternating positive and negative permittivity will respond to electromagnetic radiation as a homogeneous effective medium with anisotropic dielectric permittivity[1], at least in the long wavelength limit. When electric field is perpendicular to this 1D periodic structure along lateral direction, the behavior of this system becomes very interesting: the existence of resonance phenomenon definitely leads to the occurrence of high index[2] at some specific frequency, which is very scarce in natural material. We can tune the resonance frequency either by altering the plasma frequency of metallic mesh structure or by changing the ratio of layer thicknesses. Furthermore, the thing which makes us amusing is that high transmission is observed in ABA structure[3] by this resonance. Using finite-difference-time-domain (FDTD) simulation, we design a metallic net structure to realize this idea. In the near future, microwave experiments will be performed to verify our predictions. 1D periodical structure The occurrence of high index The left : System geometry. The layers are infinite in extent in the xy plane. The right: the equivalent effective media model. Metallic Net Structure This introduces a mechanism for creating artificial high refractive index metamaterials. Reflection and Transmission ABA structure with different air gaps between layers A and B Rigorous criterion for perfect transmission If the gap is bigger than the critical thickness, no perfect transmission exists and the maximum transmittance is less than unity. References: [1] D. Bergman, Physics Reports 43, 377 (1978). [2] J. T. Shen, Peter B. Catrysse, and Shanhui Fan, Physical Review Letters 94,197401 (2005). [3] Lei Zhou, Weijia Wen, C. T. Chan, and Ping Sheng, Physical Review Letters 94, 243905 (2005).