Overview%20of%20Metamaterials - PowerPoint PPT Presentation

About This Presentation
Title:

Overview%20of%20Metamaterials

Description:

... Introduction to Metamaterials - Definition of Metamaterial - How ... capable of directionality - same antenna can be used for multiple frequency ... – PowerPoint PPT presentation

Number of Views:250
Avg rating:3.0/5.0
Slides: 24
Provided by: JayB163
Learn more at: https://ewh.ieee.org
Category:

less

Transcript and Presenter's Notes

Title: Overview%20of%20Metamaterials


1
Overview of Metamaterials and their Radar and
Optical Applications Jay B Bargeron
2
Overview
  • - Personal Background in Metamaterials
  • - Introduction to Metamaterials
  • - Definition of Metamaterial
  • - How Metamaterials work
  • - Microwave Metamaterials
  • - Optical Metamaterials
  • - Conclusions

3
Personal Background
4
Introduction to Metamaterials
5
Introduction to Metamaterials
Electromagnetic waves - Not much difference
between 1kHz (?300km) and 1THz (?0.3mm) Why
cant optical light (Terahertz frequency) go
through walls like microwaves? - Material
response varies at different frequencies -
Determined by atomic structure and arrangement
(10-10 m). How can we alter a materials
electromagnetic properties? - 1 method is to
introduce periodic features that are electrically
small over a given frequency range, that appear
atomic at those frequencies
6
Introduction to Metamaterials
Whats in a name? - Meta- means altered,
changed or higher, beyond Why are they called
Metamaterials? - Existing materials only exhibit
a small subset of electromagnetic properties
theoretically available - Metamaterials can
have their electromagnetic properties altered to
something beyond what can be found in nature. -
Can achieve negative index of refraction, zero
index of refraction, magnetism at optical
frequencies, etc.
7
Definition of Metamaterial
  • - Metamaterial coined in the late 1990s
  • - According to David R. Smith, any material
    composed of periodic, macroscopic structures so
    as to achieve a desired electromagnetic response
    can be referred to as a Metamaterial
  • -(very broad definition)
  • -Others prefer to restrict the term Metamatetial
    to materials with electromagnetic properties not
    found in nature
  • - Still some ambiguity as the exact definition
  • - Almost all agree the Metamaterials do NOT rely
    on chemical/atomic alterations.

8
How Metamaterials Work
  • Example How to achieve negative index of
    refraction
  • -
  • - negative refraction can be achieved when both
    µr and er are negative
  • - negative µr and er occur in nature, but not
    simultaneously
  • -silver, gold, and aluminum display negative er
    at optical frequencies
  • -resonant ferromagnetic systems display negative
    µr at resonance

9
How Metamaterials Work
Example How to achieve negative index of
refraction ? What if the structures that cause
this frequency variance of µr and er at an
atomic scale could be replicated on a larger
scale? ? To appear homogeneous, the structures
would have to be electrically small and
spaced electrically close ? The concept of
metamaterials was first proven in the microwave
spectrum.
10
Microwave Metamaterials
? Early metamaterials relied on a combination of
Split-ring resonators (SSRs) and conducting
wires/posts ? SSRs used to generate desired µr
for a resonant band of
frequencies. ? Conducting posts are polarized
by the electric field,
generating the desired er
for all frequencies below a
certain cutoff frequency.
11
Microwave Metamaterials
? Other approaches for fabricating microwave
metamaterials have also been developed -
Transmission line models using shunt inductors
for affecting er and series capacitors for
affecting µr. This method, however, is
restrained to 1D or 2D fabrication
12
Microwave Metamaterials
? Conducting wires/posts can be replaced with
loops that mimic an LC resonating
response. SRRs are still required to affect µr.
13
Microwave Metamaterials
Proven areas of Microwave Metamaterials ?
Microwave cloaking by bending EM rays using
graded indices of refraction ? Currently
limited to relatively narrow bandwidths and
specific polarizations ? Limited by
resonant frequency response
14
Microwave Metamaterials
Proven areas of Microwave Metamaterials ?
Sub-wavelength antennas - n 0 in
metamaterial - capable of directionality - same
antenna can be used for multiple frequency
bands - currently used in Netgear wireless
router (feat. right) and the LG Chocolate
BL40
15
Microwave Metamaterials
Tuneable metamaterials ? Consider a 2-D
metamaterial, with series capacitance to affect
its EM response - This capacitance can be tuned
via ferroelectric varactors, affecting the index
of refraction of the material ? The size of the
split in SRRs can also be adjusted, from
fully closed to fully open (see Fig.
right) ? Capable of achieving phase
modulation of up to 60 degrees ? Applications in
phased-arrays, beam forming, and beam
scanning
16
Microwave Metamaterials
Planar microwave focusing lens ?Researchers at
University of Colorado have achieved a planar
array for focusing microwave radar -Though not
touted as metamaterial, meets the requirements
under the broad definition of metamaterials. The
Perfect Lens ?J.B. Pendry theoretically described
how a rectangular lens with n -1 could make a
perfect lens capable of resolving
sub-wavelength features. -Researchers in China,
using a planar Transmission Line type of
metamaterial to focus a point source (480 MHz) ,
managed to achieve sub-diffraction focusing down
to 0.08?)
17
Faster than light transmission lines?
Could this be possible? - recall that v c / n,
where v is the phase velocity. - if
then phase velocity will be greater than
c! Reality Law of Causilty - We cannot see into
the future OR even the present - While phase
velocity can exceed c, group velocity cannot -
Any change in energy/frequency will propagate
through the metamaterial slower than c.
18
Optical Metamaterials
Fabrication/Design Challenges for optical
metamaterials ? Smaller wavelength smaller
features - Coupling between elements becomes
more serious ? Metals response to
electromagnetic waves changes at higher
frequencies. - Metal no longer behaves as
perfect electrical conductors (dielectric
losses need to be taken into account) - A
frequency is eventually reached where the energy
of the oscillating, excited electrons becomes
comparable to the electric field. When this
occurs, the metals response is known as
plasmonic - Resistive and dielectric losses
become much more significant
19
Optical Metamaterials
? Most research on optical metamaterials has been
at the theoretical stage - Mathematically
characterizing nanoscale plasmonice effects. -
Computer simulations of proposed designs. ?
Relatively little work has been done with
physically realized optical metamaterials
20
Optical Metamaterials
? Rare example of 3D optical metamaterial. Gold
nanostructures with 70nm spacing between
layers.
21
Optical Metamaterials
?Experimental measurements of the previous
optical metamaterial
perpendicular polarized waves
parallel polarized waves
22
Conclusions
? Introduction of metamaterials in 1990s opened
new possibilities in electromagnetics. ?
Successful implementation of metamaterial
technology in the microwave spectrum. ?
Inherent difficulties exist in fabricating
optical metamaterials ? Most work to date
related to modeling proposed designs ? Little
work, so far, on successful application of
optical metamaterials
23
Fin
Questions???
Write a Comment
User Comments (0)
About PowerShow.com