ups applications-2 - washington state...
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MoS2 photoelectron energy distribution spectra intensity as a function of "binding” energy and photon energy.
Photon energies: Ne (I) 16.8 eV, He (I) 21.2 eV, Ne(II) 26.9 eV, He (II) 40.8 eV, and He (IIβ) 48.4 eV. Note that the relative intensity in peaks changes in the distributions with photon energy. This is due to cross-section σ changes for the “d” and “p” region of the VB.
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How is this related to the electronic structure of the material, what is the significance of the intensity variations?
To answer these questions, let us again look at the 3-step model that was first proposed by Berglund and Spicer (C. N. Berglund and W. E. Spicer, Phys. Rev. A136, 1030, 1964).
Initial Block state with energy Ei (allowed state with a periodicity determined by the periodic potential of the crystal lattice). These electrons are then excited (1) by the photon into a conduction band state at Ej (2). The excited electron finally escape from the surface (matching at the vacuum interface between the excited state and some free electron state in vacuum). This state can be represented by a single plan wave e ip.r ≈ (3).
ik
jk
jk
'jk
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The contribution to the photocurrent I (hν,ε) with some initial state energy Ei = ε (analyzer set to ε) can be expressed as follows: Where T (k) is some function expressing the probability of transport and escape (steps 2 and 3) and where the dipole matrix element expresses the optical excitation (step 1). A is the vector potential, ∇ gradient and the δ functions express the fact that Ei and Ej are separated by hν and the second that the energy analyzer is “tuned “ to pick out the initial state Ei. Illustration of several importance effects: 1. Density of states 2. Matrix elements 3. Transport effects
( ) ) )dkE(εhEδ(EkAkT(k),hIiij
2
fi−−−∇•∞∫ δνεν
2
ijkAk ∇•
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Theoretical calculations versus photoemission spectrum
Let us assume that we are slowly varying transport functions and matrix elements so that it can be given by: The two δ functions define 2 intersecting surfaces in reciprocal space and if the integral is transformed to a line integral around the line of intersection the photocurrent is expressed as: The integral diverges when both gradient terms go to zero (band becomes essentially “flat”). But (1/∇(E)) dE is the density of states in an energy interval dE. So, if we neglect the singularities, the photoemission measures the overall density of states in the valence band of the solid and can be compared directly with calculated band diagram.
Density of States
) )dkE(εhEδ(EIiij
−−−∞∫ δν
∫ ∇∇∞
)()(dlI
ikjkEE
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Very good agreement between theory and experiment in the “p” region. No contribution of the “s” states is seen in the He II data. This is due to a very small value of the dipole matrix element.
No “s” contribution because
02≈∇• ij kAk
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Dipole Matrix Elements
Photoionization Cross-section
The absence of the ‘s’ state in the SnSe2 He (II) spectrum can be explained by looking at the matrix element
At a given photon energy hν and for a fixed final state the matrix element will vary depending on whether is s, p, d or f like.
In practice, the ‘s’ cross-section is extremely low above about 10 eV until we reach soft x-ray energies. Therefore only p, d and f electrons will be detected in the energy range of 0 - 50 eV (UPS).
2
ijkAk ∇•
fk
ik
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Calculated cross-section
for certain rare-gas shells
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So, back to molybdenum disulfide, the VB states are formed from Mo 4d and S 3p electrons. The band near the EF is purely ‘d’ like and the remaining structure comes from covalent bonding band based on the S 3p electrons. Some mixing p/d character is also expected. Spectra between 5 and 40 eV Based on the plot cross-section vs. PE energy shown in the previous slide the 3p states dominates below 25 eV and the 4d states above 25 eV. Bands 2 and 4 are purely S 3p and finally bands 3 and 5, expected to have a mixed character p/d. Atomic character of the states cause intensity changes
5 4
3
2 1
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Energy loss introduced by electron-electron interactions (scattering and secondary emission). If these electrons escape the spectrum will display peaks that will move as the photon energy is changed. Structure which ‘moves’ between NeI and HeI spectra is assigned to secondary electron emission (identified by bars)
Transport Effects
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Band Theory and PE Spectrum (electron energy distributions)
He II
“s”
2s 1s forbidden but 2p 1s allowed
“p”
XPS
Because the C – C bond distance in graphite ~ 1.4 Å strong interatomic interactions > than in diamond. The VB electron distribution is important theoretically and experimentally.
UPS spectrum is closer to the DOS data P. M. Williams, Handbook of x-ray and ultraviolet photoelectron spectroscopy, edited by D. Briggs, Heyden&Son Ltd, 1977.
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C. Bandis, L. Scudiero et al, Surface Science, 442 (1999) 413-419
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Dispersion Measurements Far more useful is the direct E ---> k
(dispersion) measurement obtained
by angular photoemission studies.
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By measuring the energy of the peak position with respect to the angle θ and using the expression k// α E sinθ. The dispersion relation graph that plots the binding energy-wave vector dependence for graphite can be obtained.
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The data obtained here (BE vs k// ) for the first Brillouin zone agrees well with the calculated bands of Painter and Ellis (G.S. Painter and D. E. Ellis, Phys. Rev. B1, 4747, 1970) shown here.
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Adsorption on solids Adsorption of a monolayer of CO on polycrystalline Pt and Ni. From this kind of data the following schematic of molecular orbitals could be obtained:
5σ 1π 4σ 5σ, 1π and 4σ
contribute to the PE spectrum
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Polymer (P3HT) thermally deposited on clean Ag
18 16 14 12 10 8 6 4 2 0
2 1 0
2 1 0
In
tens
ity (a
bitra
ry u
nits
)
Binding Energy (eV)
P3HT thickness Ag foil 0.25 nm 0.32 nm 0.44 nm 0.75 nm 1.0 nm 1.9 nm 3.1 nm
0.56 eVEF
Clean Ag
P3HT 0.44 nmHOMO cutoff
0.8 eV
4 3 2 1 0
0.55 eV
∆ = 0.56 eV (interface dipole moment) and HOMO (VBM) = 0.55 eV
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∆
Evac (P3HT)
Bind
ing
Ener
gy (e
V)
EF
ΦAg
hν =
21.
2 eV
eD Evac (Ag)
Vb
φh
UPS spectrum of Ag Energy diagram UPS spectrum of P3HT on Ag
EFvac CB
VBM
18
16
14
12
10
8
6
4
2
0 EFVB
hν =
21.
2 eV
L. Scudiero & al. applied Surface Sciences 255 (2009) 8593-8597
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Hybrid Nanocomposites for Electronics Applications (P3HT-Ag nanoparticles)
P3HT
Clean Ag foil
∆
∆3
P3HT
(c)
∆2
∆1
3:1
1:1
1:3
3:1
1:1
1:3
Ag
(b) (a)
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Blend film 3:1 Blend film 1:1 Blend film 1:3
0.55 eV HOB edge
Fermi-level
∆3(3:1)
ΦBlend film
(3.77 eV)
0.79 eV
∆2(1:1)
ΦBlend film
(3.47 eV)
1.36 eV
∆1(1:3)
ΦBlend film
(3.37 eV)
ΦP3HT film
(3.71 eV)
P3HT film
0.60 eV
0.56 eV
EF
Ag
Evac
ΦAg
(4.27 eV)
It is possible to tune the value of the barrier height ( ) from 0.55 to 1.36 eV by simply varying the composition of the blend film (P3HT/Ag ratio ranging from 3:1 to 1:3) and changing the electronic properties of nanocomposite materials.
L. Scudiero & al. ACS Applied Materials & Interfaces
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Combining UV-Vis measurements and/or computational chemistry to measure or calculate band gap of materials and UPS measurements of the HOMO (VB energy) a energy diagram can be easily drawn. Example: C60(CN)2 deposited on semiconductor by spin coating for photovoltaic applications. UV-Vis measurements give a band gap energy = 2.18 eV, Calculation (TD-DFT) gives 1.99 eV (isolated molecule, energy difference between HOMO-LUMO). UPS measurements yield HOMO (valence band max) position at 1.1 eV.
∼1.1 eV
∼1.82 eV
Koppolu, Gupta, Scudiero, Solar Energy Materials & Solar Cells 95 (2011) 1111–1118
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CBm
Vacuum level
VBM
CBm
Φ1 Φ2
IPD IPA
EAD EAA
Photon
e-
h+
VBM
P3HT C60(CN)2 Si n –type exposed to air
Fermi level
φSi = 4.49 eV
Evac-Si
CBm
∆C60(CN)2 ~ - 0.12 eV
5.71 eV
1.1 eV
3.54 eV
4.7 eV
2.82 eV
∆P3HT ~ + 0.5 eV
VBM
CBm
Photovoltaic effect (PV)
HOMOa = 1.1 eV => IP = 5.54eV LUMOa = 3.54 eV => EA = 3.42eV
Glass
ITO PEDOT:PSS
P3HT:C60(CN)2
Al
40 nm
120 nm
80 nm I
V
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UPS-HeI
DFT-GGA (generalized gradient
approximation)
d-band center
Pd
Catalysis applications (bimetallic systems) : XPS and UPS combined
1. Bonding between different materials leads to charge transfer, from surface and bulk atoms to maintain a common Fermi level. (e.g. energy shift of d peak (XPS) and d-band center of substrate shift (UPS)). 2. Typically elements having initially the larger fraction of empty states in their valence band gain electrons (Goodman et al. Science 257 (1992) 897). Behavior different then bulk alloys. (eg. For monolayer film of Pd (4d band: electron population 0.974—empty =0.026, Ni substrate 3d band filled 0.888 and empty= 0.112 electrons will transfer from Pd to Ni) 3. Electronic perturbation => electron deficiency in surface atoms (less efficient at backdonation to adsorbate) => alters chemical properties. (e.g. reduction of CO desorption temperature) 4. Typically scales with the binding energy shift of overlayer Pd (XPS). The larger the BE shift is, the greater is the decrease in temperature. 5. d-band center shift predict or contradict the directionality of the charge Transfer (XPS data).
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+0.5 eV
XPS Pd 3d5/2
EF
d-centers
He I (21.2 eV)
Energy (E)
N(E
)
2
1
Resulting in a d-band center downshift of 0.7eV for the CuPd (blue dashed line) w.r.t. the Fermi level.
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2nd Edition E. H. Rhoderick and R. H. Williams Oxford Science Publications
Metal- Semiconductor Contacts
Electron states in solids and at surfaces
Density of states for n-type Si (a) and band structure as a function of distance (b). The important surface parameter for semi-conductor is the electron affinity χs defined as the difference in energy between an electron at rest outside the surface and an electron at the bottom of the conduction band just inside the surface
I is the minimum energy needed to remove an electron from the VB. gs
EI += χ
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Band bending near the surface could be cause by either surface states on a free surface or a metal overlayer.
Typical PE spectrum
for n-type SC
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(Theoretical variation of cross-section). Likelihood of ionization of an electron from a given orbital in an atom.
Photoionization Cross-section of C
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1. Elemental dependency of the cross-section on photon energy for C, N and O.
2. Difference in cross-section for different orbitals for Phosphorus.
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References • Handbook of x-ray and ultraviolet photoelectron spectroscopy, edited by D. Briggs, Heyden&Son Ltd, 1977.
• P.M. Williams same Handbook. p.313 – 340
• M. Thompson, P.A. Hewitt and D. S. Wooliscroft same Handbook, p341 -379
• B. L. Sharma, Plenum Press, New York