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Electron spectroscopy James N. O’Shea School of Physics & Astronomy Nottingham Nanoscience and Nanotechnology Centre University of Nottingham. SMALL Kick-off meeting , Madrid| Jan 2011. Outline Something to study: Dye molecules Chemical information: XPS Molecular orbitals: PES & XAS
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Electron spectroscopyJames N. O’SheaSchool of Physics & AstronomyNottingham Nanoscience and Nanotechnology CentreUniversity of Nottingham SMALL Kick-off meeting , Madrid| Jan 2011
Outline Something to study: Dye molecules Chemical information: XPS Molecular orbitals: PES & XAS Adsorption geometry: XAS Charge transfer dynamics: RPES SMALL Kick-off meeting , Madrid| Jan 2011
Charge injection interface How is the molecule bonded to the surface? What can we say about the electronic coupling? LUMO HOMO
A model dye-sensitised system LUMO HOMO
Vacuum level KE hv BE L. Patthey et al, J. Chem. Phys. 110, 5913 (1999) Core-level photoemission LUMO HOMO Core level
Intensity (arb. Units) Ethyl-trifluoroacetate K. Siegbahn et al Chemical shift (eV) Chemical information with x-ray photoelectron spectroscopy (XPS) Although the core-level electrons are not directly involved in the formation of bonds, a change in the valence electrons (chemical state) will change the potential a core-electron feels and therefore modify the binding energy.
Vacuum level KE hv BE Core-level photoemission LUMO HOMO Core level L. C Mayor et al, J. Chem. Phys. 129, 114701 (2008)
Electron spectroscopy is surface sensitive We all know that x-rays themselves can penetrate deep into most matter… …but the electrons coming out can only travel through a couple of layers without banging into something along the way.
KE hv BE Occupied states: valence photoelectron spectroscopy Vacuum level
BEres BEcore hv Unoccupied states: x-ray absorption spectroscopy (XAS) Vacuum level
Molecular orientation & XAS J. Ben Taylor et al, J. Chem. Phys. 127, 134707 (2007)
Vacuum level hv RPES: Participator decay Participator electrons leave the atom in a final state just like valence photoemission. They track with constant binding energy. LUMO HOMO N1s
Vacuum level hv RPES: Spectator decay Spectator electrons leave the atom in a final state just like Auger decay with an extra electron in an unoccupied state. They track with constant kinetic energy…like Auger electrons but shifted up. LUMO HOMO N1s
Vacuum level hv RPES: Auger decay Charge transfer of the originally excited electron leaves Auger decay as the only non-radiative core-hole decay option. They track with constant kinetic energy. LUMO HOMO N1s
LUMO LUMO+1 LUMO+2 Participator J. Schnadt et al, Nature 418, 621 (2002) J. Schnadt et al, Nature 418, 621 (2002) Bi-isonicotinic acid on rutile TiO2(110)
The benchmark The sensitivity of RPES compared to XAS intensity is assessed for the decoupled molecule (multilayer) where no charge transfer is expected for any unoccupied state. A state-dependent ratio that we call C is generated for the case of an isolated molecule (in this case, C=⅓). J. Schnadt et al, Nature 418, 621 (2002)
Conclusions Chemical information: XPS Molecular orbitals: PES & XAS Adsorption geometry: XAS Charge transfer dynamics: RPES SMALL Kick-off meeting , Madrid| Jan 2011