optics, plasmonics and excitonics: connecting fundamental ... · optics, plasmonics and excitonics:...
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Optics, Plasmonics and Excitonics: Connecting Fundamental Theory to
Experiments and Applications
Emerging Topics in Optics University of Minnesota April 24, 2017
George C. SchatzNorthwestern University
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Metal nanoparticle optical property research
Teri Odom, Rick Van Duyne,Chad Mirkin,Emily Weiss, M. Ratner, Stephen Gray (Argonne)
Electrodynamics:Shengli Zou (Central Florida)Marty Blaber (Seagate)Montacer Dridi (France)Kevin KohlstedDaniel Park, Mike Ross, Marc BourgeoisDanqing Wang, Weijia WangWendu Ding, Liang-Yan Hsu
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Outline
1. Optical properties of isolated particles2. Plasmon resonances for 1D and 2D
nanoparticle arrays; lattice-plasmons and plasmon lasers
3. Plasmon resonances for 3D superlatticecrystals: plasmon-photonic interactions and metamaterials properties.
4. Plasmon-mediated exciton transport
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1.7 nm
350 400 450 500 550 600 650 700
Wavelength (nm)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Extin
ctio
n (O
ptic
al D
ensi
ty)
3.5 nm
5.2 nm
20 nm
60 nm100 nm
160 nm
Spectra of dispersed colloidal gold for selected diameters (data from Turkevich (1954), Doremus (1964))
Colloidal Gold
Extinction = absorption + scattering(color of solution=color of light not absorbed or scattered)
Michael Faraday, 1856
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E-field
e- cloud
Metalsphere
Plasmon excitation: collective excitation of the conduction electrons
osp 2
e
1shape / surroundings 2 cchemical properties 4 ne
m
+ χελ = = π
π
Plasmon (Bohm, Pines, 1952):
n=electron densityχ = shape factor (2 for sphere, >2 for spheroid)εo = dielectric constant of surroundings
Charge cloud of conduction electrons
Nuclear framework of particle
Mie Extinction for 13 nm Au spheres
0.0
0.2
0.4
0.6
0.8
1.0
Extin
ction
Effi
cienc
y
200 300 400 500 600 700 800
wavelength(nm)
2
pe
4 nemπ
ω =Langmuir plasma frequency (1929):
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Spectrum of Colloidal Silver
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The Plasmonic Periodic Table
Blaber, et al. J. Phys: Condens. Matter, 2010. 22, 143201.
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Mie Extinction for 13 nm Au spheres
0.0
0.2
0.4
0.6
0.8
1.0
Extin
ction
Effi
cienc
y
200 300 400 500 600 700 800
wavelength(nm)
20 nm
Extinction for 20 nm spheres
Extinction Cross Section = (long wavelength limit)
ε = dielectric function of metal = ε1 + iε2
2 322 2
1 2
382
( radius )( )
επλ ε ε+ +
Mie Theory (1908)
real
imaginary
Dielectric constants of Au
200 300 400 500 600 700 800
wavelength (nm)
-15.0
-10.0
-5.0
0.0
5.0
Real
or Im
agina
ry pa
rt of
diele
ctric
cons
tant
ε1
ε2
(Lorenz-Mie-Debye) Theory
G. Mie, Annalen der Physik, 26, 597-614, 1908
Gustav Mie1868-1957
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Size-Tunable Surface Plasmon Resonanceswidth95 120 145 145 145150150
Wavelength (nm)400 500 600 700 800 900
Nor
mal
ized
Ext
inct
ion
lmax565 638 720 747 782497446
height48 46 59 55 50627012042
426shape
Ag/mica
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Computational Electrodynamics Methods for Nanoparticles
Grid or Finite element methods:•Discrete Dipole Approximation•Finite Difference Time Domain Method•Whitney-form Finite Element Method
Beyond Conventional Maxwell:•Nonlocal dielectric functions•Coupled QM + EM
1H Et µ∂
= − ∇×∂
1E H Jt ε∂
= ∇× −∂
( ) ( ) ( )20p p p p
d J t J t E tdt
γ ω ε+ =
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Discrete Dipole Approximation
ik ri i 0 ij j
i jP E e A P
≠
= α −
∑
k=ω/c, rij=|ri-rj|, and rij= (ri-rj)/rij
Solve using iteration with complex conjugate gradient and FFT
( )ijikr
ij2 2ij j ij ij j ij j ij ij j3 2
ij ij
1 ikreA P k r (r P ) r P 3r r Pr r
− = × × + −
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E H Jt
ε ∂= ∇× −
∂
H Et
µ ∂= −∇×
∂
1/2 1/21/2, , 1/2, ,
1/2, ,
n nx i j k x i j k
i j k
E Et
ε+ −
+ ++
−=
∆1/2, 1/2, 1/2, 1/2, 1/2, , 1/2 1/2, , 1/2
n n n nz i j k z i j k y i j k y i j kH H H H
y z+ + − + + + + −− −
−∆ ∆
1, 1/2, 1/2 , 1/2, 1/2
, 1/2, 1/2
n nx i j k x i j k
i j k
H Ht
µ+
+ + + ++ +
−=
∆
1/2 1/2 1/2 1/2, 1/2, 1 , 1/2, , 1, 1/2 , , 1/2
n n n ny i j k y i j k z i j k z i j kE E E E
z y
+ + + ++ + + + + +− −
−∆ ∆
Finite-difference Time-Domain Method
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05
101520
300 400 500 600 700 800 900 100005
101520 76 nm 12 nm 16 nm
100 nm16 nm a
bExtinction Efficiency
Wavelength, nmMirkin, et al, Figure 5
0
300 400 500 600 700 800 900 10000
5
10
15
20
76 nm 12 nm
16 nm
b
Wavelength, nm
300 400 500 600 700 800 9000.00
0.05
0.10
335 nm
~480 nm
~670 nm
Extin
ctio
n (a
.u.)
Wavelength, nm
Silver prisms (15x75 nm) Measured spectrum
Calculated Spectrum
Induced polarization at 670 nm
y
2.667
1020
3040
45.3
4.64710203040
46.84
Y ax
is
Z axis
2.667
1020
3040
45.3
4.64710203040
46.84
R. Jin, Y. Cao, C. A. Mirkin, K. L. Kelly, G. C. Schatz, J. -G. Zheng, Science, 294, 1901-1903 (2001).
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Modeling the Spectra of Silver Bipyramids using EM
400 600 800Wavelength (nm)
Zhang, Li, Wu, Schatz, and Mirkin Angew. Chem. Int. Ed., 48, 7787, (2009)
Simulations
Extin
ctio
n
400 600 800
Experiments and simulations are in good agreement with each other.
Wavelength (nm)
Extin
ctio
n
ExperimentsAg right bipyramid
Au rod-sheath
a = 106, 131, 165, 191 nmb
a
a = 2b
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~ 1 nm precision required for theory-experiment match !!McMahon, Wang, Sherry, Van Duyne, Marks, Gray, and Schatz , JPCC, 113, 2731-2735 (2009)
90 nm Ag cube on glass: Plasmon is “split” into a blue component on the top and a red component on the bottom
Precision test of electrodynamics for silver cubes
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LSPR Control by Molecular Adsorbates:Alkanethiols
Ag
Wavelength (nm)400 600 800 1000
Extin
ctio
n
0.08
0.16
0.24564
Van Duyne et al., J. Am. Chem. Soc., 123, 1471-1482 (2001).
CH
3
CH
3
CH
3
Ag
CH (CH ) SH3 2 15
D l max = +40 nm
604
5000 nm
Δλmax
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D. L. Jeanmaire and R. P. Van Duyne, J. Electroanal. Chem. 84, 1-20 (1977)
Nanoparticles
Nanoparticles
ωexωex - ωvib
Normal Raman Spectrum (NRS) 2.5 M Pyridine
Surface - Enhanced RamanSpectrum (SERS): enhancement factor = 106
Surface Pyridine
Surface Enhanced Raman Spectroscopy (SERS)
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Plasmon enhancement factors (electromagnetic mechanism):
Absorption =~|E(ω)|2
SERS enhancement =~|E(ω)|2|E(ω’)|2~ (|E|4)ave~106-12
When molecule is in direct contact with surface there are also chemical enhancements in SERS
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Arrays of Au, Ag Nanoparticles: Optical properties strongly determined by structure
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300 400 500 600 700 800 9000
3
6
9
D/2r=521.51.251.01singleEx
tinct
ion
Effic
ienc
y
Wavelength (nm)
a
Extinction Spectra of Nanoparticle Chains
parallel
E0
Coupled multipole results for 100 30 nm spheres, parallel polarization
Parallel polarization leads to red shifts
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320 340 360 380 400 4200
3
6
9
12
c perpendicular
E0
Perpendicular polarization leads to blue shifts
5.02.01.51.251.01single
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E0
400 50 nm particles
Width=4 meV
Width=0.001meV
Shengli Zou, Nicolas Janel, and George C. Schatz, J. Chem. Phys. 120, 10871-10875 (2004).
Infinite array of 50 nm particles
Narrow lineshapes for one-dimensional arrays of silver particles spaced by the wavelength
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Particle arrays made using optical lithography show sharp lattice plasmon resonances
W. Zhou and T. Odom, Nature Nano, 6, 423 (2011), A. Yang, T. B. Hoang, M. Dridi, C. Deeb, M. H. Mikkelsen, G. C. Schatz, T. W. Odom, Nature Comm 6, 6939 (2015)
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Particle arrays made using lithography show interaction of lattice mode with a gap plasmon
Q-Y Lin et al (M. Ross, GCS, C. A. Mirkin) Nano Lett, 15, 4699 (2015)
Experiment Theory
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Al nanoparticle arrays show both dipole and quadrupole lattice plasmons
A. Yang, A. J. Hryn, M. R. Bourgeois, W-K Lee, J. Hu, G. C. Schatz, T. W. Odom, PNAS 113, 14201-6 (2016)
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Background and Motivations 26
Plasmonic LasersGain medium near plasmonic structure results in enhanced stimulated emission
Oulton,R. F. et al. (X Zhang), Nature, 461, 629-632 (2009)
Noginov, M. A. et al.(Shalaev, Stockman) , Nature, 460, 1110–1168 (2009)
Laser dye around spherical gold particle
CdSe nanowire near flat silver surface
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Nature Nano 8, 506-511 (2013)
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Coupling QM to EM at the rate constant level
1)Quantum treatment of dye molecules
2)Classical electrodynamics for nanoparticle array
Model components:
Nature Nano 8, 506-511 (2013)
Measured and calculated dispersion behavior
Measured and calculated extinction
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Coupling QM to EM at the rate constant level
3) Coupling of molecular polarization to field
22
2
( ) ( ) ( ) ( ) ( )a aa a a a
d P t dP t P t N t E tdt dt
ω ω κ+ ∆ + = ∆
2)Rate equations (derivable from Bloch equations) determine state populations, including amplified spontaneous and stimulated emission
1) Maxwell’s equations determine fields
Nature Nano 8, 506-511 (2013)
3 3 3
32 30
1 a
a
dN N N dPEdt dtτ τ ω
= − − + ⋅ ⋅
32 2
32 21
1 e
e
N dPdN N Edt dtτ τ ω
= − + ⋅ ⋅
1 2 1
21 10
1 e
e
dPdN N N Edt dtτ τ ω
= − − ⋅ ⋅
0 31
10 30
1 a
a
dN N dPN Edt dtτ τ ω
= + − ⋅ ⋅
(S5)
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Coupling QM to EM at the rate constant level
Results:(1) Emission shows threshold behavior
(2)Population inversion distribution show plasmon enhancement
Nature Nano 8, 506-511 (2013)
(3)Population inversion is pinned above the lasing threshold <50 nm from particles
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New work shows that lasing can be tuned by changing dye/refractive index with liquid gain materials
A. Yang, T. B. Hoang, C. Deeb, M. Dridi, M. Mikkelsen, GCS, T. Odom, Nature Comm., 6, 6939 (2015)
experiment theory
Laser emission: experiment
Laser emission: theory
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DNA-linked Nanoparticle Superlattices
S. Y. Park, A. K. R. Lytton-Jean, B. Lee, S. Weigand, GCS, C. A. Mirkin, Nature, 451, 553 (2008).
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2.55Å/bp 3.40Å/bp
# DNA/nanoparticle
Calculate for loading on each particle, then take smaller value
What crystal lattices occur when particles have different sizes and DNA loadings? Geometrical model: lattice is determined by crystal that has the largest DNA hybridization
Science, 334, 204-8 (2011)
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Science, 334, 204-8 (2011)
FCC
CsC
lC
r 3Si
NaC
l
BC
CAlB
2C
s6 C
60Sim
ple Cubic
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M. Jones, R. MacFarlane, B. Lee, J. Zhang, K. Young, A. Senesi, C. Mirkin, Nat. Mat 9, 913 (2010).R, H, Macfarlane, B. Lee, M. R. Jones, N. Harris, G. C. Schatz, C. A. Mirkin, Science, 334, 204-8 (2011).
DNA-linked nanoparticle superlattices:Extension to Nonspherical Particles
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Experimental Studies for Disks show Plasmon Hybridization and Fano Interference effects
• High energy anti-bonding mode
• Bonding mode with a net dipole
M. O‘Brien, M. R. Jones, K. L. Kohlstedt, GCS and CAM, Nano Lett, 15, 1012 (2015)
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For Au 3D superlattice material, effective medium approximation leads to red shifts in extinction spectra with
increasing crystal size
A. Lazarides and G. C. Schatz, J. Phys. Chem. 104, 460-7 (2000)M. B. Ross, J. C. Ku, B. Lee, C. A. Mirkin and G. C. Schatz, J. Phys. Chem. C 120, 816-830 (2016)
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38
Silver Superlattices show collective metallic response
BCC: Ag 20 nm diameter20 nm edge to edge
DielectricLSPR
Metallic
Kaylie L. Young, Michael B. Ross, Martin G. Blaber, Matthew Rycenga, Matthew R. Jones, Chuan Zhang, Andrew J. Senesi, George C. Schatz, and Chad A. Mirkin, Adv. Mat. 26, 653-659 (2013).
Re ε
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Ag superlattice aggregates: theory vs expt
Kaylie L. Young, Michael B. Ross, † Martin G. Blaber, Matthew Rycenga, Matthew R. Jones, Chuan Zhang, Andrew J. Senesi, George C. Schatz, and Chad A. Mirkin, Adv. Mater., 26, 653-659 (2013).
red: 17.1% Ag
green: 3.7% Ag
blue: 1.5% Ag
Metallic Dielectric
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DNA-linked nanoparticle superlattice crystals
Auyeung, et al., Nature 2014, 505, 73.scale bar: 5 um
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Plasmonic/Photonic Crystals made by DNA Nanoparticle Assembly Show Strong
Coupling of Plasmons and Fabry-Perot Modes
D. J. Park et al. “Photonic Crystals Realized through DNA Programmable Assembly” Proc. Natl. Aca. Sci., 2014, doi: 10.1073/pnas.1422649112.
Theory – 2D slab (EMT) Theory – 2D BCC slab (FDTD)
ExperimentFabry-Perot Modes(Scale bar 1 μm )
Volume Fraction ~1% Volume Fraction ~10%
g
e
SurfacePlasmon
CavityModes
ω
PS
600
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Ag/Au Alloy and Bimetallic Superlattice Thin FilmsM. Ross, J. Ku, B. Lee, C. A. Mirkin and G. C. Schatz, Adv. Mat., 28, 2790(2016)
Atomic vs nanoscale alloying leads to different results: reflects charge transfer at the atomic level that doesn’t occur for nanoparticles.
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Ag/Au Alloy and Bimetallic Superlattice Thin Films
Reflectivity is asymmetric as a result of the combination of gradient with lossy material.
M. Ross, J. Ku, B. Lee, C. A. Mirkin and G. C. Schatz, Adv. Mat., 28, 2790(2016)
Silver on left Gold on left
Expt Theory
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Magneto-Plasmonics Provide New Opportunities for Designing Light-Matter Interactions
Combination: plasmonic sensitivity and optical control with magneto-responsive character
Magnetic materials provide asymmetric and magneto-responsive optical properties:Kerr RotationKerr EllipticityFaraday Rotation
Plasmonic systems provide exquisitely tunable optical properties
Magnetic thin film Au Ag
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Model System: TMOKE in Co-Superlattice Thin Films
Superlattice modulates intensity and phase of light reaching the magnetic layerManifests as changes in:
• Overall reflectance of multilayer structure• Enhancement and control of TMOKE response• Unusual positive TMOKE parameter for metallic Ag superlattice
Transverse Magneto Optical Kerr Effect
Michael B. Ross, Marc R. Bourgeois, Chad A. Mirkin and George C. Schatz, J. Phys. Chem. Lett. 7, 4732-38 (2016).
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Conclusions1. Solutions of Maxwell’s equations for isolated silver and gold nanoparticles
accurately match observed extinction spectra.
2. Arrays of nanoparticles which satisfy Bragg scattering conditions lead to lattice plasmon modes with narrow lines that are of interest in subwavelength lasers.
3. 3D arrays with well defined crystal habits lead to interesting plasmonicFabry-Perot modes. There are also unique metamaterials properties associated with these materials.
4. We have developed a FDTD-based approach to describe plasmon-mediated exciton transport.