photoemission (i) spectroscopy - cheiron school...
TRANSCRIPT
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Photoemission (I)SpectroscopyCheiron School 2009
November 8, 2009 Spring-8, Japan
Ku-Ding Tsuei
National Synchrotron Radiation Research Center
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Outline1. What is photoemission spectroscopy?2. Fundamental aspects of photoemission.3. Examples.4. Increase bulk sensitivity: HAXPES.5. Challenging future directions.
General reference books:
1. "Photoelectron Spectroscopy" 3rd Ed. by S. Hufner, Springer-Verlag 2003
2. "Angle-Resolved Photoemission: Theory and Current Applications", S. D. Kevan, ed., Amsterdam; Elsevier 1992
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What is photoemission?
Photon in –> electron out (emission)
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What are the samples and probed states?
Atoms atomic orbitals (states)Molecules molecular orbitals
core level states (atomic like)Nanoprticles valence bands/states
core level states (atomic like)Solids valence bands
core level states (atomic like)
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What is photoemission spectroscopy?(photoelectron spectroscopy) (PES)
hv Monochromatizedphotons
Initial state: ground (neutral) state
sample
Electron energy analyzer
Final state: hole (excited) state
h+
e-
Ek
N(Ek)
Energy Distribution Curve (EDC)(Spectrum)
Conservation of energyEk = hv + Ei – Ef (most general expression)
Ek : photoelectron kinetic energyEi (N) : total initial state system energyEf (N-1): total final state system energy
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Single particle description of energy levels (Density of States) (most convenient in PE)
1s
2s
2p1/2
2p3/2
3s3p
Na atom Na metal
N(E)(DOS)
E
EF
Core levels
Fermi level
Valence (sp)Band(DOS)
√E (nearly free electron like)
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Hufner, Damascelli
Ek = hv – EB - φ
Conservation of energy
Energetics in PES
Ev : vacuum (energy) levelEF : Fermi (energy) levelφ = Ev – EF : work functionE0 : bottom of valence bandV0 = Ev – E0 : inner potential
Ekmax marks EF in spectra
EB measured relative to EF = 0
Usually fixed photon energy scanning not needed
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An XPS Energy Distribution Curve (EDC)
Most spectra expressedthis way
Hufner
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Ultraviolet Photoemission Spectroscopy (UPS)UV He lamp (21.2 eV, 40.8 eV)valence band PE, direct electronic state info
X-ray Photoemission Spectroscopy (XPS)(Electron Spectroscopy for Chemical Analysis) (ESCA)
x-ray gun (Al: 1486.6 eV, Mg: 1253.6 eV)core level PE, indirect electronic state info
chemical analysis
Synchrotron radiation:continuous tunable wavelengthvalence band: <100 eV, maybe up to several keVcore level: 80-1000 eV, maybe up to several keV
depending on core level binding energies
Light sources and terminology
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Inelastic Electron Mean Free Path (IMFP)
Minimum due to electron-electron scattering, mainly plasmons
PE is a surface sensitive technique! (requires UHV)
High energy photoemission: several keV to increase bulk sensitivity
I(d) = Io e-d/λ(E)
λ(E): IMFP depending on kinetic energy relative to EF
UPS
XPS
SR (VUV,SX,HX)
Hufner
Univeral curve
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Core level binding energies arecharacteristic of each orbital ofeach element
Finger prints
Core level BE independent of photon energy used
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ESCA (XPS) hv = Mg Kα = 1253.6 eV
Core level photoemission: chemical analysis of elements
Different photon energy different relative cross section for various core levels Relative intensity changes with photon energy
PJW, NSRRC
Synchrotron hv = 160 eV
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410 409 408 407 406 405 404 403
Binding Energy (eV)
Pho
toem
issi
on In
tens
ity (a
. u.)
Dm = 18 A
Dm = 32 A
(a)
Dm = 42 A
Bulk CdSe
Cd 3d5/2
59 58 57 56 55 54 53 52
Dm = 18 A
Dm = 32 A
Dm = 42 A
Binding Energy (eV)
Pho
toem
issi
on In
tens
ity (a
. u.)
(b)
Bulk CdSe
Se 3d
10 8 6 4 2 0 -2
Dm = 18 A
Dm = 32 A
Bulk CdSe
Dm = 42 A
Inte
nsity
(a. u
.)
Binding Energy (eV)
A case study of IMFPapplied to PE of CdSenano particles with tunable SRHow to choose photonenergies for valenceand different core levelswith the max surfacesensitivity?
Actual choices:Cd 3d5/2 : 480 eVSe 3d: 120 eVValence band: 50 eV
Ek ~ 45-74 eV, most surface sensitiveWu, PRB 2007 NSRRC
bulk componentsurface component
Surface core level shift(chemical and/or environmental)
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Core level photoemission: chemical shift
higher oxidation state => higher BE
higher emission angle more surface sensitive
(IMFP) Pi, SS 2001 NSRRC
BE
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Core electron ionized by photons or high energy electronsNon-radiative core hole decay
Auger electron emissionRadiative decay
Fluorescent x-ray emission
Auger Electron Spectroscopy
Comparison between PES and AESPES: constant BE, Ek shift with changing photon energyAES: constant Ek, apparent BE shift with changing photon energy(synchrotron)
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Conceptually intuitive, Simple calculation works
Photoemission Process
Rigorous, requires sophisticated calculation
Hufner, Damascelli
Explicitly responsible for IMFP Implicitly responsible for IMFP
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Schematic wave functions of initial and final states(valence band initial states)
(a) Surface resonance(b) Surface state(c) Bulk Bloch state
(d) Surface resonance(e) in-gap evanescent state(f) Bulk Bloch final state
Bulk band gap
Bulk band gap
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Electron kinetic energy inside and outside of solids
Inner potential: EV – E0
Concept of inner potential is used to deduce 3D band structure from PE dataassuming free electron like final state inside solids
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Angle Resolved Photoemission Spectroscopy (ARPES)
Electron emission angle: өPhoton incident angle: ψ, s- and p-polarization
θ
x
z
xz plane: crystal symmetry plane
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Conservation of linear momentum parallel to the surface
θ
θ
sin)(5123.0)Å(
sin2
1-//
2//
⋅=
⋅=
eVEk
Emk
k
kh
k┴ (inside) ≠ k ┴ (outside) because of inner potential
Ultimately to deduce band dispersion E(k┴) or E(k┴,k||)
Normal emission: θ = 0, or k|| = 0, most used detection geometry
Important for 3D and 2D band mapping
k||(inside) = k ||(outside)
Conservation of liner momentum
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Band Mapping (3D) E(k┴, k||=0)
Vertical transition (using visible, uv and soft x-rays) at normal emission
For hard x-ray photon momentum cannot be neglected
Using different hv at normal emission to map out E(k┴)
k┴Pilo, Damarscelli
1st B.Z.
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Bulk band structure and Fermi surfaces
Fermi surfaces:
Electron pockets and hole pocketsRelated to Hall coefficientElectric conductivityMagnetic susceptibility
Cu
Small dispersion d-bandmore localized state
Large dispersion sp-bandextended state
(nearly free electron like) sp-band
Dispersion of a band can tell how localizedor extended a state is in a solid Hufner
Gap below EF(=0) at L-point
L Γ X
(111) (001)
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Quantum well states: manifestation of particle in a box in real materials
z
Quantized discretely along z-directionEnergy levels depend on film thickness L
Nearly free electron like in xy-plane
Ag(111) thin films expitaxiallygrown on Au(111) substrate
EAu Ag
Bulk projected bands along ΓLof Au and Ag, respectively
EFBand gapbelow EF Ag QWS can
exist withinAu gap
L
vacuum
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k|| = 0EDCs
2D Int.plots
Clean Au(111) surface state
Deposit 22 ML Agat 37 Kdisordered form
Ag S.S.
Ag QWS
Anneal to 258 KAtomically flat22 ML thin film
Luh et al.PRL 2008NSRRCBL21B1
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Anneal to 180 KQWS appearminimal flat dispersionSmall localizeddomains withinxy-plane
Anneal to 258 KWell developeddispersionLarge, good crystalline domainsin xy-plane
Anneal to 189 KCoexistence oftwo kinds ofdispersion
Same QWS energies Same crystalline filmthickness along zeven though lateralcrystalline domainsgrow from small tolarge
Proposed growth model
Annealing Temp
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One-particle spectral function near EF measured by ARPES with many-particle correction (quasi-particle)
22 )],("[)],('[),("1),(
ωωεωω
πω
kkkkA
k Σ+Σ−−Σ
−=
),("),('),( ωωω kikk Σ+Σ=Σ
εk : single particle energy without many-particle correctionω= 0 : EF
Self energy correction due to interaction with phonons, plasmonsand electrons, etc.
Real part: shift observed peak energy from single particle energyImaginary part: peak FWHM = 2 Σ”
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Peak position Kink ~25 meV due to electron-phonon scattering
Featurelesssingle particledispersioncurve
Peak position – single particle curve
Width due toelectron-electronscattering ~ ω2
Width due toelectron-phononscattering
Const bkg widthdue to impurities
Total W=We-e+We-ph+Wim
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( )νδσ hEEpA ififdd
−−⋅∝Ω ∑ Ψ⋅Ψ
2
Photoemission cross section in single particle approximation (1st step in 3-step model, inside bulk)
ifififfi rApAprAM ΨΨ⋅∝ΨΨ⋅≅Ψ⋅Ψ= )0()0()(
A : polarization vectorΨi : initial state (orbital) wave function (1s, 2p, valence states etc.)
contain orbital symmetry informationΨf : final state (orbital) wave function ~ exp(ik.r) for high kinetic energy
photoelectrons, no orbital symmetry retains (non-resonance photoemission)(orbital symmetry in final state is important in near edge absorption measurements (XAS) and in intermediate state in resonance photoemission)Dipole transition rule: Δl = +1
dipole approximation
Symmetry selection rule for initial (valence) state governed by matrix elemente.g. suppose A(0) = Ax, <eikz | x | ψi(x) > = 0 if ψi(-x) = +ψi(x)Important for crystalline samples
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Symmetry of states in ARPES determined by selection ruleexample: LiCu2O2
a
bc
Cu2+
O2-Li+
Cu+
Cu2+O2-2 chains along b-axis built by
edge sharing Cu2+O2-4 plaquettes
Cu2+ : 3d9 spin-1/2
Quasi-1D spin-1/2 chain
Coexistence of spin-spiral long range orderwith ferroelectricity multiferronic
Ideal spin-1/2 1D chain system will have spin-charge separation of photo-hole decayDoes it happen on LiCu2O2?Must be checked by ARPES (not discussed further)
Will focus on symmetry of states determined byARPES with polarization
a = 2b
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Basic building unit: CuO4 planar plaquetteCu
O
O
OOxy
Highest energy state: Cu 3dxy and O 2p antibonding (AB) state
Still keeps dxy symmetry
dxy
dxy
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Ax’x’
y’ Normal emission |f> = exp(ikz) even to all symmetry op[i> even to y’z-plane, Ax’ odd to y’z-plane<f| Ax’ |i> = <+| - | +> = 0, forbidden
Off-normal emission [f> = exp(ikz+kx’) even to x’z-plane|i> even to x’z-plane, Ax’ even to x’z-plane<f| Ax’ |i> = <+| + | +> != 0, allowed
Normal emission [f> = exp(ikz) even to all symmetry op[i> odd to xz-plane, Ax even to xz-plane<f| Ax |i> = <+| + |-> = 0, forbidden
Off-normal emission |f> = exp(ikz+ikx) even to xz-plane|i> odd to xz-plane, Ax even to xz-plane<f| Ax |i> = <+| + |-> = 0, forbidden
xy
Ax
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Inte
nsity
(arb
. uni
t)
3.0 2.0 1.0 0.0Binding Energy (eV)
Γ(0)
Y (Γ′)(1.1)
hν = 22 eV
(X)(0.55)
1
3.0 2.0 1.0 0.0Binding Energy (eV)
Γ (0)
Y (Γ′)(1.1)
hν = 47 eV
(X)(0.55)
Inte
nsity
(arb
. uni
t)
3.0 2.0 1.0 0.0Binding Energy (eV)
Γ(0)
(X)(0.55)
Y(Γ′)(1.1)
hν = 73 eV
Inte
nsity
(arb
.uni
t)
3.0 2.0 1.0 0.0Binding Energy (eV)
Γ(0)
Y' (1.5)
hν = 47 eV
xy
Ax
xy
Ax
xy
AxAx’x’
y’
Focus on B.E. = 0.7 eV peak at Y’
The highest energy peak at 0.7 eV has dxy symmetry!
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ARPES for valence band PE uses primarily VUV light because1. Better absolute photon energy resolution for most BLs designed
as const ΔE/E.2. Better photoionization cross section at low photon energy.3. Better momentum resolution for a given angular resolution.
Δk|| = 0.5123 √(Ek) cos(θ) Δθ
SX ARPES has been tried for increasing bulk sensitivity, morefree electron like final states and reduced matrix element effects.The increasing bulk sensitivity will be discussed.
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NSRRC U9 BL21B1 BL and high resolution photoemission end station
CGM
U9 undulator
ScientaSES 200analyzer
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Hemispherical electron energy analyzer
R1 : radius of inner sphereR2 : radius of outer sphereRo=(R1+R2)/2 : mean radius
and along electron pathV1: inner potentialV2: outer potentialEp: pass energy = electron
kinetic energy along meanradius
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Resonance photoemission(near-edge absorption followed by Auger likeelectron emission)
e.g. Ce3+ (4f1)
Direct PE
EF
e-
4f4f
3d/4d
e-
EF4f4f
3d/4d
4f4f
3d/4d
Absorption +Auger like emission
intermediate state
Resonance PE
4f mixed with other DOS
Intensity enhanced by absorptionPredominantly 4f DOS
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Comments on photoelectron IMFP
Valence band PE using VUV and SX has IMFP near minimum,very surface sensitive. It is great to probe surface electronic structuresuch as surface states and surface resonances.
Many strongly correlated systems have electronic structure sensitive tocoordination, thus surface contains different electronic structure from that of deeper bulk. Great surface sensitivity posts a serious problem to probe true bulk properties.
Need larger IMFP by using higher energy photons to enhance bulk sensitivity.
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surface surface
By using Ce 3d 4f Res. PE near 880 eV surface 4f component becomesgreatly reduced compared to 4d 4f Res. PE near 120 eV, the resulting spectraare closer to true bulk 4f DOS.
2000
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Drive to go to even higher photon energies into hard x-ray regime
HArd X-ray PhotoEmission Spectroscopy (HAXPES)
HAXPES not only reach even closer to true bulk properties of strongly correlated systems, but also becomes capable of probinginterface electronic structure, Very difficult using conventional VUV/SX.
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HAXPES example: Hard x-ray photoemission on Si-high k insulator buried interface
Annealed sampleHfSix formation
hv = 6 keV, ΔE ~ 0.24 eVTake-off angle dependence => non-destructive depth profileCan probe buried interface at 35 nm ! (achievable only by hard x-ray PE)
Kobayashi, APL 2003 SPring-8
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NSRRC HAXPES project at SPring-8
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Electron IMFP (probing depth) and Cross section
567
10
2
3
4
567
100
2
Inel
asti
c M
ean
Fre
e P
ath
(A)
5 6 7
102
2 3 4 5 6 7
103
2 3 4 5 6 7
104
Kinetic Energy (eV)
Au SiO2
XPS
Higher Ek for deeper probing depth or more bulk sensitivity, for stronglycorrelated systems and interface propertiesPhotoemission signal (σ⋅λ) decreases rapidly > 1 keVNeed photon source of higher flux/brightness (modern SR), efficient BL design and good electron analyzersHAXPES is a low count rate, photon hungry experiment!
Why Hard X-rays?
HAXPES
UPS
SP8
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Optical design concept
DM: horizontal dispersion
HRM: vertical dispersion
Diamond (111) reflection6-12 keV
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Layout of the side beamline of BL12XU
6-12 keV using diamond (111) reflectionDesigned for HAXPES
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Diamond monochromator: installed Aug. 3, 2007
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Diamond glows even under weak radiation at a fully opened gap 50 mm.Its shape is like a trapezoid.
Strong radiation at a small gap 10 mm~ 6 keV makes the diamond glow like a bright mercury-vapor lamp. Strong scattered radiation causes snow like noise on camera.
February, 2008
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High Res.Mono.KB focusmirrorsRotationalplatform
End stationMBS energy analyzer
Commission of SPring-8 BL12XU SL HAXPES end station – Apr. Jul. 2009
Horizontalsetup
Verticalsetup
Low resolution w/o HRM8 keV
Medium resolution Si(333) HRM, 7.6 keV
KB Focus at sampleAft HRM Si(333)7.6 keV38x38 microns
In collaboration withCologne U of Germany
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Challenging future directions of Photoemission Spectroscopy
1. ARPES at submicron to tens of nanometer scale, using Schwatzchild optics or zone plates.Need brighter light sources.
2. Time-resolved PES. Pump-probe: dynamics.Need efficient detection and brighter sources.lasers or laser+SR.
Thanks for your attention