Why is work function almost always in the range 4-6 eV?

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SUMMARY

The work function for metals, semiconductors, polymers, and ceramics typically falls within the range of 4-6 eV, but notable exceptions exist. For instance, metals like magnesium (3.66 eV), cesium (2.1 eV), calcium (2.9 eV), and potassium (2.3 eV) demonstrate work functions outside this range. In semiconductors, the work function is influenced by the band gap, with materials from the antimonide family exhibiting work functions lower than 3 eV, making them suitable for photocathode applications with green lasers. The discussion highlights the relationship between electron affinity, band bending, and the work function in semiconductors.

PREREQUISITES
  • Understanding of work function in materials science
  • Knowledge of band gap theory in semiconductors
  • Familiarity with electron affinity concepts
  • Basic principles of Fermi levels and vacuum levels
NEXT STEPS
  • Research the work function of various metals and their applications
  • Explore the properties of antimonide semiconductors for photocathode use
  • Study the effects of band bending on electron affinity in semiconductors
  • Investigate the relationship between Fermi levels and vacuum levels in different materials
USEFUL FOR

Materials scientists, semiconductor researchers, and engineers involved in the development of electronic devices and photocathodes will benefit from this discussion.

free_electron
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This is the case with metals semiconductors polymers and ceramics I have checked on the web. Still looking for exceptions...
 
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free_electron said:
This is the case with metals semiconductors polymers and ceramics I have checked on the web. Still looking for exceptions...

Er... I think there's enough of a spread here that one can't actually say that. For metals, which would be a more accurate representation of a "work function", you can have Mg at 3.66 eV, cesium at 2.1, calcium at 2.9, potassium at 2.3, etc... So there's plenty outside of the range you mentioned.

For semiconductors and band insulators, it depends very much on the band gap. I believe that the antimonide familly of semiconductor work function are lower than 3, which is why it is being considered as photocathode material using "green" laser rather than UV.

Zz.
 
okay, I hadn't checked most of the periodic table yet :P

But even band gaps have a limited range, add to that a limited range of distances from the Fermi to the vacuum level.

Do these ranges come from somewhere?

Thanks.
 
free_electron said:
okay, I hadn't checked most of the periodic table yet :P

But even band gaps have a limited range, add to that a limited range of distances from the Fermi to the vacuum level.

Do these ranges come from somewhere?

Thanks.

The electron affinity in semiconductors are not that big when compared with metals. In fact, with band bending, I can make it go negative, resulting in negative electron affinity material. So in semiconductors, the work function is dominated by the band gap.

Zz.
 

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