1. Photonic- Phononic- and Meta-Material Group Activities
TETY
Photonic- Phononic- and Meta-Material Group Activities
Mainly theory, also experiment (characterization)
Main research topics
Metamaterials
Photonic crystals
Plasmonic structures
Web:

2. Main group members Senior C. M. Soukoulis (TETY & FORTH)
M. Kafesaki (FORTH & TETY)
E. N. Economou (FORTH)
N. Katsarakis (TEI & FORTH)
Th. Koschny (FORTH &ISU)
PhD
T. Gundogdu (exp)
Post-docs
G. Kenanakis
R. S. Penciu
A. Reyes-Coronado
S. Foteinopoulou
Students
N. Vasilantonakis
Ch. Mavidis
I. Tsiapa
Web:

3. Main group members Senior C. M. Soukoulis (TETY/FORTH)
M. Kafesaki (FORTH/TETY)
E. N. Economou (FORTH)
N. Katsarakis (TEI/FORTH)
Th. Koschny (FORTH/ISU)
PhD
T. Gundogdu (exp)
Post-docs
G. Kenanakis (exp)
N. H. Shen
R. S. Penciu
A. Reyes-Coronado
S. Foteinopoulou
Students
N. Vasilantonakis (exp)
Ch. Mavidis
I. Tsiapa (exp)

4. Main collaborations FORTH-IESL
TETY
FORTH-IESL
G. Konstantinidis’ group - microfabrication
M. Farsari’s group - direct laser writing
S. Tzortzakis’ group - THz time domain spectroscopy
M. Wegener’s Karlsruhe Institute of Technology, Germany
E. Ozbay’s Bilkent University, Turkey
J. Pendry’s Imperial College, UK
V. Orera Univ. of Zaragoza, Spain
Profactor company, Austria ….

5. Publications ( )
TETY
Publications number (with TETY affiliation): ~70
(3 Science, 4 PRL, 4 OL, 26 PRB, 7 APL, 11 OE)
Citation number for these publications: ~2000

6. Current EU Projects TETY
Acronym
Name
Type
PHOME
PHOtonic MEtamaterials
FP7-ICT-FET
ENSEMBLE
ENgineered SElf-Organized Multi-component structures with novel controllaBLe Electromagnetic Functionalities
FP7 NMP
NIM_NIL
Large Area Fabrication of 3D Negative Index Materials by NanoImprint Lithography
ECONAM
Electromagnetic Characterization Of NAnostructured Materials
Coordination Action FP7
COST Action MP0702, "Towards Functional Sub-wavelength Photonic Structures"
COST Action MP0803, "Plasmonic Components and Devices"

7. Projects (last 6 years) TETY
Acronym
Name
Type
PHOME
PHOtonic MEtamaterials
FP7-ICT-FET
ENSEMBLE
ENgineered SElf-Organized Multi-component structures with novel controllaBLe Electromagnetic Functionalities
FP7 NMP
NIM_NIL
Large Area Fabrication of 3D Negative Index Materials by NanoImprint Lithography
ECONAM
Electromagnetic Characterization Of NAnostructured Materials
Coordination Action FP7
FENIM
Frequency Extension of the Negative Index Materials
US Air Force
Metamorphose
METAMaterials ORganised for radio, millimeter wave and PHOtonic Superlattice Engineering
FP6 - Network of Excellence (NoE)
PHOREMOST
PHOtonics to REalize MOlecular Scale Technologies
FP6-NoE
DALHM
Development and Analysis of Left Handed Materials
FP5-IST-FET
COST Action MP0702, "Towards Functional Sub-wavelength Photonic Structures"
COST Action MP0803, "Plasmonic Components and Devices"

8. Metamaterials
TETY
Artificial, structured (in sub-wavelength scale) materials
Electromagnetic (EM) properties derive from shape and distribution of constituent units (usually metallic & dielectric components)
EM properties not-encountered in natural materials
Electrical permittivity
Magnetic permeability
EM properties
Possibility to engineer electromagnetic properties

9. Left-handed metamaterials
TETY
Negative electrical permittivity () Negative magnetic permeability ()
Sov. Phys. Usp. 10, 509 (1968)
Negative ε, μ, n
Novel and unique propagation characteristics in those materials!

10. Novel phenomena in left-handed metamaterials
TETY
Backwards propagation (opposite phase & energy velocity)
S=E×H S

11. Backwards propagation in left-handed metamaterials
TETY
Backwards propagation in left-handed metamaterials
Left-handed slab
Source

12. Novel phenomena in left-handed metamaterials
TETY
Backwards propagation (opposite phase & energy velocity)
S=E×H S
Negative refraction
AIR
LHM, n2<0 θ2
source θ1
LHM
air
Flat lenses -
“Perfect” lenses (subwavelength resolution)
Zero-reflection possibility
Opposite Doppler effect
Opposite Cherenkov radiation ……
Interesting physical system
New possibilities for light manipulation  important potential applications

13. Application areas of left-handed metamaterials
TETY
New solutions and possibilities in
Imaging/microscopy
Lithography
Data storage
Communications and information processing (subwavelength guides, optimized/miniaturized antennas & filters, improved transmission lines ...) ….
Exploiting the subwavelength resolution capabilities of LHMs

14. Metamaterials beyond negative index High index metamaterials
TETY
High index metamaterials
Shrinkage of devices
Cloaking
Low index metamaterials
Parallel beam formation
Indefinite media
Hyperlensing
Single-negative media
Bi-anisotropic media

15. Designing left-handed metamaterials
TETY
Most common approach: Merging structures of negative permittivity (ε) with structures of negative permeability (μ)
Split Ring Resonator (SRR), Pendry, 1999
Short-slabs-pair, Shalaev, 2002 j
Negative permeability: Structures of resonant loop-currents C L
Negative permittivity: Continuous wires E

16. Microwave (mm-scale) structures
TETY

17. Micro and nano-scale structures
TETY
Fabricated in MRG
780 nm
1.4 μm

18. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional isotropic left-handed metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative refraction and other interesting effects (chiral, anisotropic, polaritonic metamaterials)
Explore novel phenomena and possibilities in metamaterials

19. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional isotropic left-handed metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative refraction and other interesting effects (chiral, anisotropic, polaritonic metamaterials)
Explore novel phenomena and possibilities in metamaterials

20. THz and optical structures
Optical metamaterials
THz and optical structures
TETY
5m
Five layers !
Fabricated in Crete
Silver in polyimide
Optics Letters 30, 1348 (2005)
~6 THz
1.4 μm
780 nm

21. “Magnetic” metamaterials response in high frequencies
Optical metamaterials
TETY
“Magnetic” metamaterials response in high frequencies
Al metal
Glass substrate
No negative permeability at arbitrarily high frequencies
Results not affected by metal losses
Reducing a
a: u.c. size
Saturation of response frequency in small length scales (a<500 nm)
Vanishing of negative permeability band-width
Weakening of permeability resonance

22. Magnetic permeability by scaling down the structures
Optical metamaterials a
Reducing size
Weakening of magnetic resonance (no negative μ) at small scales

23. Explaining the observed response
TETY
Consideration of metal dispersive response in the conductivity:
Zhou et. al., 2005
Tretyakov, 2007
Solymar, 1976
Shvets et. al., 2005
For uniform scaling:
a: lattice constant
Inductive term (electrons inductance) due to electrons inertia (“Difficulty” to accelerate finite mass particles with such high rates)
ωp= metal plasma frequency
γm=metal collision frequency l S

24. Explaining the observed response
Optical metamaterials
Explaining the observed response
TETY
Consideration of electrons’ kinetic energy, Ee besides magnetic energy, EM (Ee becomes comparable to EM in small scales)
Ee can be considered through an equivalent inductance, Le
For uniform scaling:
a: lattice constant
V: wire effective volume
ve: electrons velocity
ne: e- number density
Zhou et. al., PRL, 2005
Penciu et al, PRB, 2010

25. Optical metamaterials with gain
TETY
Gain atoms (4-level) embedded in host medium: In Finite Difference Time Domain Method are driven oscillators which couple to the local E field
pump
Lasing ωa
Rate equations:
Driven oscillators:
Same method for examining lasing threshold in photonic crystals (with M. Farsari)
Maxwell’s equations:
σa is the coupling strength of P to the external E field and ΔN=N2-N1
C. Soukoulis’ collaboration with Karlsruhe and MRG
Phys. Rev. B: 79, (Rapid) (2009)

26. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional isotropic left-handed metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative index behaviour (chiral or anisotropic metamaterials)
Explore novel phenomena and possibilities in metamaterials

27. Towards 3D isotropic left-handed materials
New designs/approaches
Towards 3D isotropic left-handed materials
TETY 1D
Gold in polyimide
Re(n)/Im(n)|n = -1 = 5
Double ~200 THz (1.5 μm) 2D
Double ~160 THz
FORTH & ISU, Opt. Express, 2009

28. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional isotropic left-handed metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative index behaviour (chiral or anisotropic metamaterials)
To explore novel phenomena and possibilities in metamaterials

29. Switchable and tunable metamaterials The principle:
TETY
The principle: UV
PRB, 79, (R) (2009)
Collaboration with S. Tzortzakis’ group
Blue-shift tunable metamaterials & Dual-band switches

30. Blue-shift tunable metamaterials & Dual-band switches
TETY
Blue-shift tunable metamaterials & Dual-band switches
Collaboration with S. Tzortzakis’ group
Blue-shift tunable metamaterials & Dual-band switches
PRB, 79, (R) (2009)
(c)

31. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative refraction and other interesting effects (chiral, anisotropic, polaritonic metamaterials)
Explore novel phenomena and possibilities in metamaterials

32. Negative refractive index in chiral media
New designs/approaches
Negative refractive index in chiral media
TETY
Chiral structure: not-identical to its mirror image
Different index for left- and right- handed circularly polarized waves
Alternative path to achieve negative index
Besides negative index:
Polarization rotation
Circular dichroism
Negative index
Large polarization rotation
Large circular dichroism

33. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative refraction and other interesting effects (chiral, anisotropic, polaritonic metamaterials)
Explore novel phenomena and possibilities in metamaterials

34. Novel phenomena and possibilities in metamaterials
TETY
Super-lensing in anisotropic “negative” metamaterials
Electromagnetically-induced-transparency in metamaterials
Repulsive Casimir force in chiral metamaterials

35. Novel phenomena and possibilities in metamaterials
TETY
Super-lensing in anisotropic “negative” metamaterials
Electromagnetically-induced-transparency in metamaterials
Repulsive Casimir force in chiral metamaterials

36. Superlensing in anisotropic metamaterials
TETY
Superlensing in anisotropic metamaterials
dSource d
dImage z x
Sub-wavelength resolution possibility in anisotropic metamaterials z x
Perfect lensing conditions:
Propagating components:
Omnidirectional total transmission
Evanescent components: Excitation of dispersionless surface modes
Possibility for thin “lenses”! (less influenced by losses)

37. Negative refraction by an anisotropic left-handed slab
TETY
Anisotropic “perfect” lens: Negative refraction & focusing
Negative refraction by an anisotropic left-handed slab
Focusing in an anisotropic left-handed slab

38. Novel phenomena and possibilities in metamaterials
TETY
Super-lensing in anisotropic “negative” metamaterials
Electromagnetically-induced-transparency (EIT) in metamaterials
Repulsive Casimir force in chiral metamaterials

39. Novel phenomena/possibilities
EIT in metamaterials
TETY
Coupling of a “bright” (coupled to incident field) and a “dark” (not coupled to incident field) resonance leads to strong dispersion & low absorption
Demonstration of realistic structures exhibiting EIT effect ( low loss – slow light)
Strong coupling
Weak coupling

40. Novel phenomena and possibilities in metamaterials
TETY
Super-lensing in anisotropic “negative” metamaterials
Electromagnetically-induced-transparency in metamaterials
Repulsive Casimir force in chiral metamaterials

41. Repulsive Casimir force in chiral metamaterials
Novel phenomena/possibilities
Repulsive Casimir force in chiral metamaterials
TETY
Casimir force: force between two uncharged plates in vacuum
Origin of the Casimir Force
Vacuum (zero point) energy, E, between plates increases with separation, causing an attracting Casimir force, FC. Dimensional reasoning gives d F
Detrimental in MEMs
Hendrik Casimir ( )
Strongest force between two neutral objects (d<10nm)

42. Repulsive Casimir force in chiral metamaterials (2)
Novel phenomena/possibilities
Repulsive Casimir force in chiral metamaterials (2)
TETY
Calculating Casimir force
General recipe: 1) Obtain classically all EM eigenmodes
2) Calculate the zero point energy of these eigenmodes
Vacuum
The eignemodes are TM (electric or p-waves, surface plasmons) and TE (magnetic or s-waves) d
Chirality of the same sign in materials 1,2  positive contribution to f  reduced attraction and even repulsion!

43. Repulsive Casimir force in chiral metamaterials (3)
Novel phenomena/possibilities
Repulsive Casimir force in chiral metamaterials (3)
TETY
Casimir energy vs separation of chiral slabs
repulsive Casimir force
zero Casimir force
and stable equilibrium
E/Ahck3
Phys. Rev. Lett. 103, (2009).
ωk ~ chirality strength
k0d
Chiral metamaterial slabs with electric, magnetic, and chiral response functions  a repulsive Casimir force for sufficiently strong chirality

44. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative refraction and other interesting effects (chiral, anisotropic, polaritonic metamaterials)
Explore novel phenomena and possibilities in metamaterials
Photonic crystals
Plasmonic systems
Besides metamaterials ?

45. Lasing threshold for 2D inverse photonic crystals (TM)
TETY
Lasing threshold for 2D inverse photonic crystals (TM)
Air
Gain
Thickness: 8400 nm E k H
Lattice constant a = 840 nm
Width of square hole: w = 540 nm
Emission frequency: 100 THz
Dielectric constant of gain: 11.7
Much lower lasing threshold (at upper band edge) than bulk gain

46. Main investigation aims/directions
TETY
Analyze, understand, optimize and tailor metamaterial response
Achieve optical metamaterials – reduce losses in metamaterials
Achieve three-dimensional metamaterials
Create switchable and tunable metamaterials
Devise/analyze new designs and approaches for negative refraction and other interesting effects (chiral, anisotropic, polaritonic metamaterials)
Explore novel phenomena and possibilities in metamaterials
Thank you.
Photonic crystals
Plasmonic systems
Besides metamaterials ?