Post on 26-Jan-2016
description
1.The emblematic example of the EOT-extraordinary optical transmission (EOT)-limitation of classical "macroscopic" grating theories-a microscopic pure-SPP model of the EOT
2.SPP generation by 1D sub- indentation-rigorous calculation (orthogonality relationship)-the important example of slit-scaling law with the wavelength
3.The quasi-cylindrical wave-definition & properties-scaling law with the wavelength
4.Multiple Scattering of SPPs & quasi-CWs-definition of scattering coefficients for the quasi-CW
How to know how much SPP is generated?
General theoretical formalismGeneral theoretical formalism
1) make use of the completeness theorem for the normal modes of waveguides
Hy=
Ez=
2) Use orthogonality of normal modes
(z)(x)Ha(z)H(x)α(x)α (rad)σσ σSP
(z)(x)Ea(z)E(x)α(x)α (rad)σσ σSP
(x)α(x)α2(z)Ez)(x,Hdz SPy
(x)α(x)α2(z)Hz)(x,Edz SPz
PL, J.P. Hugonin and J.C. Rodier, PRL 95, 263902 (2005)
x
General theoretical formalismGeneral theoretical formalism
xexp[-Im(kspx)]
x
x/a
SPe
SPee S
P
General theoretical formalism applied to
gratings
General theoretical formalism applied to grooves
ensembles
• 11-groove optimized SPP coupler with 70% efficiency.• The incident gaussian beam has been removed.
General theoretical formalism
0
0.1
0.2
0.3
0.4
• 11-groove optimized SPP coupler with 70% efficiency.• The incident gaussian beam has been removed.
General theoretical formalism
• 11-groove optimized SPP coupler with 70% efficiency.• The incident gaussian beam has been removed.
0
0.1
0.2
0.3
0.4
1.Why a microscopic analysis?-extraodinary optical transmission (EOT)-limitation of classical "macroscopic" grating theories-a microscopic pure-SPP model of the EOT
2.SPP generation by sub- indentation-rigorous calculation (orthogonality relationship)-the important slit example-scaling law with the wavelength
3.The quasi-cylindrical wave-definition & properties-scaling law with the wavelength
4.Multiple Scattering of SPPs & quasi-CWs-definition of scattering coefficients for the quasi-CW
SPP generation
n2
n1
+(x) -(x)
n2
n1
SPP generation
+(x) -(x)
n2
n1
SPP generation
n2
n1
+(x) -(x)
1) assumption : the near-field distribution in the immediate vicinity of the slit is weakly dependent on the dielectric properties
2) Calculate this field for the PC case
3) Use orthogonality of normal modes
Analytical model
PL, J.P. Hugonin and J.C. Rodier, JOSAA 23, 1608 (2006).
012
1
1/2
221
2
Iw'nn1
Iw
nεε
nn
π4αα
(x)α(x)α2(z)Ez)(x,Hdz SPy
(x)α(x)α2(z)Hz)(x,Edz SPz
Valid only at x = w/2 only!
tota
l SP
exc
itat
ion
pro
bab
ility
results obtained for gold
Tot
al S
P e
xcit
atio
n e
ffic
ien
cy
solid curves (model)
marks (calculation)
Question: how is it possible that with a perfect metallic case, ones gets accurate results?
Question: how is it possible that with a perfect metallic case, ones gets accurate results?
describe geometrical properties-the SPP excitation peaks at a value w=0.23 and for visible frequency, ||2 can reach 0.5, which means that of the power coupled out of the slit half goes into heat
EXP. VERIFICATION : H.W. Kihm et al., "Control of surface plasmon efficiency by slit-width tuning", APL 92, 051115 (2008) & S. Ravets et al., "Surface plasmons in the Young slit doublet experiment", JOSA B 26, B28 (special issue plasmonics 2009).
n2
n1
+(x) -(x)
Analytical model1) assumption : the near-field distribution
in the immediate vicinity of the slit is weakly dependent on the dielectric properties
2) Calculate this field for the PC case
3) Use orthogonality of normal modes
012
1
1/2
221
2
Iw'nn1
Iw
nεε
nn
π4αα
n2
n1
+(x) -(x)
-Immersing the sample in a dielectric enhances the SP excitation ( n2/n1)
-The SP excitation probability ||2 scales as ||-1/2
1) assumption : the near-field distribution in the immediate vicinity of the slit is weakly dependent on the dielectric properties
2) Calculate this field for the PC case
3) Use orthogonality of normal modes
012
1
1/2
221
2
Iw'nn1
Iw
nεε
nn
π4αα
describe material properties
Analytical model
PL, J.P. Hugonin and J.C. Rodier, JOSAA 23, 1608 (2006).
+(x) -(x)
+(x) -(x)
Grooves
S S
S = + [t0 exp(2ik0neffh)] / [1-r0 exp(2ik0neffh)]
PL, J.P. Hugonin and J.C. Rodier, JOSAA 23, 1608 (2006).
groove
S S
S = + [t0 exp(2ik0neffh)] / [1-r0 exp(2ik0neffh)]
0 0.2 0.4 0.6 0.80
1
2
3
h/
S
Can be much larger than the geometric aperture!
=0.8 µm
=1.5 µm
gold
S = + [t0 exp(2ik0neffh)] / [1-r0 exp(2ik0neffh)]
S S
r
r = r + 2 exp(2ik0neffh)] / [1-r0 exp(2ik0neffh)]
Grooves
PL, J.P. Hugonin and J.C. Rodier, JOSAA 23, 1608 (2006).
1.Why a microscopic analysis?-extraodinary optical transmission (EOT)-limitation of classical "macroscopic" grating theories-a microscopic pure-SPP model of the EOT
2.SPP generation by sub- indentation-rigorous calculation (orthogonality relationship)-the important slit example-scaling law with the wavelength
3.The quasi-cylindrical wave-definition & properties-scaling law with the wavelength
4.Multiple Scattering of SPPs & quasi-CWs-definition of scattering coefficients for the quasi-CW
G
If =', the scattered field is unchanged : E'(r')=E(r'/G)
'
Hinc
H'inc= Hinc
r'
r'/G
'
- All dimensions are scaled by a factor G- The incident field is unchanged Hinc()=Hinc(')
The difficulty comes from the dispersion : ' '/ = G2 (for Drude metals)
A perturbative analysis fails
Unperturbed system
E' = jµ0H' H' = -j(r)E'
Perturbed system
E = jµ0H H = -j(r)E -jE
Es=E-E' & Hs=H-H'Es = jµ0Hs Hs = -j(r)Es –jE
Indentation acts like a volume current source : J= -jE
(E' H')
(E H)
c1c1
One may find how c1 or c1 scale.
E(r-r0)
A perturbative analysis fails
"Easy" task with the reciprocity
c1c1
Source-mode reciprocityc1 = ESP
(1)(r0)J
c1 = ESP(1)(r0)J
provided that the SPP pseudo-Poynting flux is normalized to 1
½ dz [ESP(1) HSP
(1))]x = 1
ESP = N1/2 exp(ikSPx)exp(iSPz), with N||1/2/(40)
J(r-r0)
c1c1
One may find how c1 or c1 scale.Then, one may apply the first-order Born approximation (E = E'Einc
/2).Since Einc ~ 1, one obtains that dielectric and metallic indentations scale differently.
E(r-r0)
A perturbative analysis fails
~ 1 for dielectric ridges
~ for dielectric grooves
~ for metallic ridges
100
101
10-1
100
(results obtained for gold)H. Liu et al., IEEE JSTQE 14, 1522 (2009 special issue)
Numerical verificationNumerical verification
HS
P|
-1/2
(µm)
100
101
10-1
100
(results obtained for gold)
Numerical verificationNumerical verification
HS
P|
-1/2
(µm)
H. Liu et al., IEEE JSTQE 14, 1522 (2009 special issue)
100
101
10-1
100
(results obtained for gold)
Numerical verificationNumerical verification
HS
P|
-1/2
(µm)
H. Liu et al., IEEE JSTQE 14, 1522 (2009 special issue)
100
101
10-1
100
(results obtained for gold)
Numerical verificationNumerical verification
(µm)
HS
P|
-1/2
H. Liu et al., IEEE JSTQE 14, 1522 (2009 special issue)
Local field corrections: small sphere (R<<)
h
b
incident wave E0
E = E0 E = E0 for small only !3b
+3b
++
+
++
--
-
--
E
J.D. Jackson, Classical Electrodynamicsh-b
Just plug in perturbation formulas fails for large .
G
'
Hinc
assumptions : the field distribution in the plane in the immediate vicinity of the slit becomes independent of the metallic permittivity
(as ||). (the particle dimensions are larger than the skin depth)
'
H'inc= Hinc
G
'
Hinc
assumptions : the field distribution in the plane in the immediate vicinity of the slit becomes independent of the metallic permittivity
(as ||). (the particle dimensions are larger than the skin depth)
'
H'inc= Hinc
G
'
Hinc
assumptions : the field distribution in the plane in the immediate vicinity of the slit becomes independent of the metallic permittivity
(as ||). (the particle dimensions are larger than the skin depth)
'
H'inc= Hinc
G
'
Hinc
assumptions : the field distribution in the plane in the immediate vicinity of the slit becomes independent of the metallic permittivity
(as ||). (the particle dimensions are larger than the skin depth)
'
H'inc= Hinc
G
'
Hinc
'
The initial launching of the SPP changes : HSP |-1/2
H'inc= Hinc
')1/2