Difference between revisions of "Photoelectron Spectrometer XPS and UPS"
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===What is the Problem?=== [[Image:Surface_electron_spectroscopies.jpg|thumb|right|400px |XPS uses high energy X-ray photons to excite “core” electrons in the near-surface region UPS uses lower energy photons in the deep UV region to excite valence electrons.]] | ===What is the Problem?=== | ||
[[Image:Surface_electron_spectroscopies.jpg|thumb|right|400px |XPS uses high energy X-ray photons to excite “core” electrons in the near-surface region UPS uses lower energy photons in the deep UV region to excite valence electrons.]] | |||
OLEDs and OPVs consist of thin films of organic materials, sandwiched between contacting electrodes. We need analytical tools which tell us: | OLEDs and OPVs consist of thin films of organic materials, sandwiched between contacting electrodes. We need analytical tools which tell us: | ||
*Elemental composition of metal, metal oxide and organic surfaces (top 1-10 nm) | *Elemental composition of metal, metal oxide and organic surfaces (top 1-10 nm) | ||
Revision as of 08:18, 22 April 2009
What is the Problem?
OLEDs and OPVs consist of thin films of organic materials, sandwiched between contacting electrodes. We need analytical tools which tell us:
- Elemental composition of metal, metal oxide and organic surfaces (top 1-10 nm)
- The molecular state of those elements in that same region
- The frontier orbital energies which control rates of charge transfer, photopotentials, onset voltages, etc.
What is our approach? Physics of XPS and UPS
We use high-vacuum surface electron spectroscopies: X-ray photoelectron spectroscopy and UV-photoelectron spectroscopy to provide the elemental, molecular and energetic information we require about these materials.
