Introduction to X-ray Photoelectron Spectroscopy (XPS) XPS which makes use of the photoelectric effect, was developed in the mid-1960
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1 Introduction to X-ray Photoelectron Spectroscopy (XPS) X-ray Photoelectron Spectroscopy (XPS), also known as Electron Spectroscopy for Chemical Analysis (ESCA) is a widely used technique to investigate the chemical composition of surfaces. XPS which makes use of the photoelectric effect, was developed in the mid s s by Kai Siegbahn and his research group at the University of Uppsala, Sweden.
2 Photoemission of Electrons Incident X-rayX Ejected Photoelectron Free Electron Level (vacuum) Conduction Band Fermi Level 2p 2s Valence Band L2,L3 L1 XPS spectral lines are identified by the shell from which the electron was ejected (1s, 2s, 2p, etc.). The ejected photoelectron has kinetic energy: 1s K KE= hv BE - φ Following this process, the atom will release energy by the emission of a photon or Auger Electron.
3 2p 2s Auger Electron Emission Conduction Band Valence Band 2p 2s Conduction Band Valence Band L2,L3 L1 Free Electron Level Fermi Level 1s 1s K L electron falls to fill core level vacancy (step 1). KLL Auger electron emitted to conserve energy released in step 1. 1 The kinetic energy of the emitted Auger electron is: KE=E(K)-E(L2) E(L2)-E(L3). E(L3).
4 XPS Energy Scale - Binding energy BE = hv - KE - Φ spec Where: BE= Electron Binding Energy KE= Electron Kinetic Energy Φ spec = Spectrometer Work Function Photoelectron line energies: Not Dependent on photon energy. Auger electron line energies: Dependent on photon energy.
5 XPS spectrum of Vanadium Auger electrons Note the stepped background Only electrons close to surface can escape elastically (λ 63%, 3λ 95%)) Electrons from deeper in sample undergo inelastic collisions while traveling to the surface giving rise to the stepped background Empirical models can be used to subtract the backgorund
6 X-ray Photoelectron Spectrometer Hemispherical Energy Analyzer Computer System Outer Sphere Magnetic Shield Inner Sphere Analyzer Control X-ray Source Electron Optics Sample 54.7 Lenses for Energy Adjustment (Retardation) Lenses for Analysis Area Definition Position Sensitive Detector (PSD) Multi-Channel Plate Electron Multiplier Resistive Anode Encoder Position Computer Position Address Converter
7 Cylindrical mirror electron energy analyzer Hemispherical electron energy analyzer
8 water X-ray source X-rays ~15,000 Volts e- Tungsten Filament Mg(Kα) : hν = ev Al(Ka) : hν = ev
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12 Note that most XPS peaks appear as doublets A little quantum mechanics is needed to understand why this is the case Cu 2p 2p 3/2 2p 1/2 Electron quantum numbers orbital momentum: l = 0,1,2,3 (s, p, d, and f orbitals) spin momentum: s = +½, -½ total momentum: j = l + s 19.8 Peak Area 1 : Binding Energy (ev) Since s can be +½ or -½, each level with l >0 is split into two sublevels with an energy difference known as the spin-orbit splitting. The degeneracy of each of these levels is 2j+1 Orbital l j degeneracy Electron level 1s 0 1/2 1 1s 2s 0 1/2 1 2s 2p 1 1/2 2 2p 1/2 2p 1 3/2 4 2p 3/2 3d 2 3/2 4 3d 3/2 3d 2 5/2 6 3d 5/2 4f 3 5/2 6 4f 5/2 4f 3 7/2 8 4f 7/2
13 Orbital l j degeneracy Electron level 2p 1 1/2 2 2p 1/2 2p 1 3/2 4 2p 3/2 Cu 2p 2p 3/2 2p 1/ Peak Area 1 : Binding Energy (ev)
14 Orbital l j degeneracy Electron level 3d 2 3/2 4 3d 3/2 3d 2 5/2 6 3d 5/2 Ag 3d 3d 3/2 3d 5/2 6.0 Peak Area 2 : Binding Energy (ev)
15 Orbital l j degeneracy Electron level 4f 3 5/2 6 4f 5/2 4f 3 7/2 8 4f 7/2 Au 4f 4f 5/2 4f 7/ Peak Area 3 : Binding Energy (ev)
16 What information can you obtain from XPS? Identification of elements near the surface and surface composition Local chemical environments Oxidation states of transition metals Valence band electronic structure Morphology of thin films
17 Sampling Depth The universal electron scattering curve Mean Free Path, λ (Å) Electron Energy (ev) Electron mean free path is energy dependent Sampling depth is materials dependent XPS is surface sensitive but samples more than just the surface
18 Elemental Shifts Binding Energy (ev) Element 2p3/2 3p Δ Fe Co Ni Cu Zn
19 Electron Binding Energies Binding Energy, ev Atomic Number
20 Chemical Shifts In addition to the identity of the element and the orbital (s,p, d, f) electron binding energies depend on: (1) the formal oxidation state of the atom (2) the local chemical environment Both (1) or (2) cause small binding energy shifts (< 5 ev) An increase in oxidation state causes the binding energy to increase due to a decrease in the screening of the bound electron from the ion core. The ability of XPS to determine oxidation states is used extensively in catalysis research.
21 Oxidation States V(2p 3/2 ) Vanadium foil V 0 V 0 V ev ev O V 2 O 5 V 5+
22 0.5 ML VO x - XPS O 1s VO x /CeO 2 (111) VO x /TiO 2 (110) O 1s 10-3 torr O 2 V 2p 3/2 V 2p 3/2 V ev 10-7 torr O 2 V ev Just deposited V ev V 2p 1/2 V 2p 3/ Binding energy, ev V ev V 2p 1/2 V 2p 3/2 d 10-3 torr O K c b 10-7 torr O K As deposited a Clean substrate Binding energy, ev Binding energy, ev 500
23 Chemical Shifts - Electronegativity Effects Local chemical environment can also cause small shifts in XPS peak positions Functional C(1s)Binding Energy Group (ev) hydrocarbon C-H, C-C amine C-N alcohol, ether C-O-H, C-O-C Cl bound to C C-Cl F bound to C C-F carbonyl C=O Electronegative substituents decrease the electron density on the carbon atom causing a small in crease in the C(1s) binding energy δ+ δ- C-F
24 XPS of Polyethylene-terephthalate O C C O CH 2 CH 2 n O O Quantitative elemental analysis Chemical state analysis
25 Final State Effects - Shake-up features Shake-up features occur when additional electron energy level transitions occur during the photoelectron emission process Primary photoemission hν Ce(3d) - Ce +4 3d 2p 2s KE = hv - BE - Φ u''' v''' u u'' u' v'' v' v 1s 3d hν 2p Shake-up process ΔE KE = hv - BE - Φ - ΔE Binding energy, ev 860 Peaks Initial State Final State Ce 4+ v,u 3d 10 4f 0 3d 9 4f 2 V n-2 Ce 4+ v'',u'' 3d 10 4f 0 3d 9 4f 1 V n-1 Ce 4+ v''',u''' 3d 10 4f 0 3d 9 4f 0 V n 2s 1s
26 Quantitative Analysis of XPS DATA Element sensitivity factors Sensitivity factor = S = f σ D λ f = x-ray flux s = photoelectron cross-section D = detector efficiency λ =electron mean free path For a homogenous sample: n 1 I 1 /S 1 = n 2 I 2 /S 2 n i = number of I atoms I i = area of I photoemission peak S = sensitivity factor for i C x = n x = I x /S x C x = concentration of element x Σn i i ΣI i /S i i
27 Relative Sensitivities of the Elements d Relative Sensitivity p 4d 4f 2 1s 0 Li B N F Na Al P Cl K Sc V M Co Cu G As Br Rb Y Nb TcRh Ag In Sb I Cs La Pr P Eu TbHo T Lu Ta Re Ir Au Tl Bi Be C O Ne M Si S Ar Ca Ti Cr Fe Ni Zn G Se Kr Sr Zr M Ru Pd Cd SnTe XeBa Ce Nd S G Dy Er Yb Hf W Os Pt Hg Pb Elemental Symbol S(F 1s ) = 1.0
28 Thin Film Morphology Vanadium Deposition on CeO 2 (111) XPS Ce 3d/ V 2p 3/2 intensity O 1s ML of vanadium deposited Layer-by-layer film growth V 2p 1/2 V 2p 3/2 ML of V V +3 V 2p 3/2 = ev CeO 2 (111) Binding energy, ev 500
29 Ar + ion source XPS Depth Profiling XPS depth profile of SiO 2 layer on silicon wafer Si(2p) ev Si 4+ (2p) ev Sputtering time
30 Scanning XPS - Provides elemental and chemical state maps of surfaces Use electrostatic lenses to select which are of the surface is analyzed Raster the x-ray beam. Requires the electron beam in the x-ray source to be rastered and a complex quartz crystal lens to focus the x-rays.
31 XPS image of a patterned polymer film line scan image
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33 XPS of Supported Catalysts Issues: Sample is not homogenous Only analyze external surface Sample charging Beam damage
34 Valence Band Photoelectron Spectroscopy Density of states near the Fermi level. Electronic states in the band gap Binding energies of valance electrons of adsorbates Need very high energy resolution to obtain useful information. He discharge lamp or synchrotron is typically used as the photon source If ultraviolet photons (rather than x-rays) are used the technique is called Ultraviolet Photoelectron Spectroscopy (UPS). Other than the photon source instrumentation is identical to that of XPS Ionized He, Produce photons at 21.2 and 40.8 ev Sample
35 UPS Spectra of Ag/Ru(001) and AuRu(001)
36 UPS Spectra of Adsorbates
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