Difference between revisions of "Photoelectron Spectrometer XPS and UPS"

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X-ray Photoelectron Spectroscopy and UV Photoelectron Spectroscopy are techniques for studying the surface characteristic of materials.
X-ray Photoelectron Spectroscopy and UV Photoelectron Spectroscopy are techniques for studying the surface characteristic of materials.


===What is the Problem?===
===Overview Physics of XPS and UPS===


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:
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*The frontier orbital energies which control rates of charge transfer, photopotentials, onset voltages, etc. see [[Work Function of Metals]]
*The frontier orbital energies which control rates of charge transfer, photopotentials, onset voltages, etc. see [[Work Function of Metals]]


===What is our approach? Physics of XPS and UPS===
 
[[Image:Surface_electron_spectroscopies.jpg|thumb|right|300px |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.]]
[[Image:Surface_electron_spectroscopies.jpg|thumb|right|300px |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.]]
We use high-vacuum surface electron spectroscopies: X-ray photoelectron spectroscopy (XPS)and UV-photoelectron spectroscopy (UPS) to provide the elemental, molecular and energetic information we require about these materials.Surface analysis is carried out in high vacuum spectrometers, with sophisticated sample handling capabilities. The sample is prepared in a chamber to which a variety of devices can be attached.   The idea is to keep the surface as clean as possible, and to selectively add monolayers of organic materials to these surfaces, without the need to break vacuum between analyses.The sample is located at the center of the analytical chamber, and positioned so that we can excite it with either X-rays or UV photons.Once the photoelectrons are ejected from the sample, they are collected by a series of focusing lenses, and then separated according to their kinetic energy in a “hemispherical” analyzer.  We use either a single “channeltron” detector (UPS) or a multi-channel detector(XPS)
We use high-vacuum surface electron spectroscopies: X-ray photoelectron spectroscopy (XPS)and UV-photoelectron spectroscopy (UPS) to provide the elemental, molecular and energetic information we require about these materials. Surface analysis is carried out in high vacuum spectrometers, with sophisticated sample handling capabilities. The sample is prepared in a chamber to which a variety of devices can be attached. The idea is to keep the surface as clean as possible, and to selectively add monolayers of organic materials to these surfaces, without the need to break vacuum between analyses. The sample is located at the center of the analytical chamber, and positioned so that we can excite it with either X-rays or UV photons. Once the photoelectrons are ejected from the sample, they are collected by a series of focusing lenses, and then separated according to their kinetic energy in a “hemispherical” analyzer.  We use either a single “channeltron” detector (UPS) or a multi-channel detector(XPS)
 


===Technique ===
[[Image:PS-surfaceanalysis.jpg|thumb|right|300px |The small sampling depth of XPS and UPS arises because most of the photoelectrons generated do NOT make it out of the solid – they are scattered below the surface and not detected.  Only those within 1-10 nm of the surface get out and can be analyzed.]]
[[Image:PS-surfaceanalysis.jpg|thumb|right|300px |The small sampling depth of XPS and UPS arises because most of the photoelectrons generated do NOT make it out of the solid – they are scattered below the surface and not detected.  Only those within 1-10 nm of the surface get out and can be analyzed.]]


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===Data interpretation===
===Significance===
<gallery widths=300px heights=200px perrow=3> Image:Xps_spectrum.png‎|Here is a typical “survey spectrum” for a clean gold surface, modified with a single monolayer of a phenyl-terminated alkanethiol.  We plot number of emitted photoelectrons on the y-axis, and their binding energy (BE) or kinetic energy (KE) on the x-axis.  The photoelectric effect applies (as first described by Einstein) – there is conservation of energy, and you can see that the BE of each photoelectron is related to the excitation source energy, the measured kinetic energy of that photoelectron, and a “work function” of the spectrometer (constant).  Each element provides us with at least one photoemission peak, with a distinct BE or KE.  
<gallery widths=300px heights=200px perrow=3> Image:Xps_spectrum.png‎|Here is a typical “survey spectrum” for a clean gold surface, modified with a single monolayer of a phenyl-terminated alkanethiol.  We plot number of emitted photoelectrons on the y-axis, and their binding energy (BE) or kinetic energy (KE) on the x-axis.  The photoelectric effect applies (as first described by Einstein) – there is conservation of energy, and you can see that the BE of each photoelectron is related to the excitation source energy, the measured kinetic energy of that photoelectron, and a “work function” of the spectrometer (constant).  Each element provides us with at least one photoemission peak, with a distinct BE or KE.  



Revision as of 08:35, 6 October 2009

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X-ray Photoelectron Spectroscopy and UV Photoelectron Spectroscopy are techniques for studying the surface characteristic of materials.

Overview Physics of XPS and UPS

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. see Work Function of Metals


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.

We use high-vacuum surface electron spectroscopies: X-ray photoelectron spectroscopy (XPS)and UV-photoelectron spectroscopy (UPS) to provide the elemental, molecular and energetic information we require about these materials. Surface analysis is carried out in high vacuum spectrometers, with sophisticated sample handling capabilities. The sample is prepared in a chamber to which a variety of devices can be attached. The idea is to keep the surface as clean as possible, and to selectively add monolayers of organic materials to these surfaces, without the need to break vacuum between analyses. The sample is located at the center of the analytical chamber, and positioned so that we can excite it with either X-rays or UV photons. Once the photoelectrons are ejected from the sample, they are collected by a series of focusing lenses, and then separated according to their kinetic energy in a “hemispherical” analyzer. We use either a single “channeltron” detector (UPS) or a multi-channel detector(XPS)

Technique

The small sampling depth of XPS and UPS arises because most of the photoelectrons generated do NOT make it out of the solid – they are scattered below the surface and not detected. Only those within 1-10 nm of the surface get out and can be analyzed.

<swf width= "640" height="480">http://depts.washington.edu/cmditr/media/pes.swf</swf>


Significance