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{{distinguish|text=[[Schottky defect]]}}
{{stub}}
[[File:Schottky-effekt.png|thumb]]
In electron emission devices, especially [[electron gun]]s, the thermionic electron emitter will be biased negative relative to its surroundings. This creates an electric field of magnitude ''F'' at the emitter surface. Without the field, the surface barrier seen by an escaping Fermi-level electron has height ''W'' equal to the local work-function. The electric field lowers the surface barrier by an amount Δ''W'', and increases the emission current. This is known as the '''Schottky effect''' (named for [[Walter H. Schottky]]) or field enhanced thermionic emission. It can be modeled by a simple modification of the Richardson equation, by replacing ''W'' by (''W''&nbsp;−&nbsp;Δ''W''). This gives the equation<ref>
The '''Schottky effect''' or '''field enhanced thermionic emission''' is a phenomenon in [[condensed matter physics]] named after [[Walter H. Schottky]]. In electron emission devices, especially [[electron gun]]s, the [[thermionic emission|thermionic electron emitter]] will be biased negative relative to its surroundings. This creates an electric field of magnitude ''F'' at the emitter surface. Without the field, the surface barrier seen by an escaping Fermi-level electron has height ''W'' equal to the local work-function. The electric field lowers the surface barrier by an amount Δ''W'', and increases the emission current. It can be modeled by a simple modification of the [[Richardson's equation|Richardson equation]], by replacing ''W'' by (''W''&nbsp;−&nbsp;Δ''W''). This gives the equation<ref>
{{cite journal
{{cite journal
|last1=Kiziroglou |first1=M. E.
|last1=Kiziroglou |first1=M. E.
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|bibcode=2008SSEle..52.1032K
|bibcode=2008SSEle..52.1032K
|doi=10.1016/j.sse.2008.03.002
|doi=10.1016/j.sse.2008.03.002
|url=https://eprints.soton.ac.uk/143941/1/Thermionic_field_emission_at_electrodeposited_Ni%25E2%2580%2593Si_Schottky_barriers.pdf
}}</ref><ref name=Orloff>
}}</ref><ref name=Orloff>
{{Cite book
{{Cite book
|last1=Orloff |first1=J.
|last1=Orloff |first1=J.
|year=2008
|year=2008
|chapter=Schottky emission
|chapter=Schottky emission
|chapterurl=http://books.google.it/books?id=y0FF19lud5YC&pg=PA6&lpg=PA6&dq=#v=onepage&q=&f=false
|chapter-url=https://books.google.com/books?id=y0FF19lud5YC&pg=PA6
|title=Handbook of Charged Particle Optics
|title=Handbook of Charged Particle Optics
|pages=5–6 |edition=2nd
|pages=5–6 |edition=2nd
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}}</ref>
}}</ref>
:<math>J (F,T,W) = A_{\mathrm{G}} T^2 e^{ - (W - \Delta W) \over k T}</math>
:<math>J (F,T,W) = A_{\mathrm{G}} T^2 e^{ - (W - \Delta W) \over k T}</math>
:<math>\Delta W = \sqrt{e^3 F \over 4\pi \epsilon_0},</math>
:<math>\Delta W = \sqrt{{q_e}^3 F \over 4\pi \epsilon_0},</math>
where ''J'' is the emission [[current density]], ''T'' is the temperature of the metal, ''W'' is the [[work function]] of the metal, ''k'' is the [[Boltzmann constant]], ''q''<sub>e</sub> is the [[Elementary charge]], ''ε''<sub>0</sub> is the [[Permittivity#Vacuum permittivity|vacuum permittivity]], and ''A''<sub>G</sub> is the product of a universal constant ''A''<sub>0</sub> multiplied by a material-specific correction factor ''λ''<sub>R</sub> which is typically of order 0.5.
where ''ε''<sub>0</sub> is the electric constant (also, formerly, called the [[Permittivity#Vacuum permittivity|vacuum permittivity]]).


Electron emission that takes place in the field-and-temperature-regime where this modified equation applies is often called '''Schottky emission'''. This equation is relatively accurate for electric field strengths lower than about 10<sup>8</sup> V&nbsp; m<sup>−1</sup>. For electric field strengths higher than 10<sup>8</sup> V&nbsp;m<sup>−1</sup>, so-called [[Field electron emission|Fowler-Nordheim (FN) tunneling]] begins to contribute significant emission current. In this regime, the combined effects of field-enhanced thermionic and field emission can be modeled by the Murphy-Good equation for thermo-field (T-F) emission.<ref>
[[File:Schottky-Emitter 01.jpg|thumb|Schottky-emitter electron source of an [[Electron microscope]]]]Electron emission that takes place in the field-and-temperature-regime where this modified equation applies is often called '''Schottky emission'''. This equation is relatively accurate for electric field strengths lower than about 10<sup>8</sup> V&nbsp; m<sup>−1</sup>. For electric field strengths higher than 10<sup>8</sup> V&nbsp;m<sup>−1</sup>, so-called [[Field electron emission|Fowler–Nordheim (FN) tunneling]] begins to contribute significant emission current. In this regime, the combined effects of field-enhanced thermionic and field emission can be modeled by the Murphy–Good equation for thermo-field (T-F) emission.<ref>
{{cite journal
{{cite journal
|last1=Murphy |first1=E. L.
|last1=Murphy |first1=E. L.
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|volume=86 |issue= 24|pages=5570–5573
|volume=86 |issue= 24|pages=5570–5573
|bibcode=2001PhRvL..86.5570M
|bibcode=2001PhRvL..86.5570M
|doi=10.1103/PhysRevLett.86.5570
|doi=10.1103/PhysRevLett.86.5570 |pmid=11415303
}}</ref> For example, excited Cs-vapours in thermionic converters form clusters of Cs-[[Rydberg matter]] which yield a decrease of collector emitting work function from 1.5 eV to 1.0–0.7 eV. Due to long-lived nature of [[Rydberg matter]] this low work function remains low which essentially increases the low-temperature converter’s efficiency.<ref>
}}</ref> For example, excited Cs-vapours in thermionic converters form clusters of Cs-[[Rydberg matter]] which yield a decrease of collector emitting work function from 1.5 eV to 1.0–0.7 eV. Due to long-lived nature of [[Rydberg matter]] this low work function remains low which essentially increases the low-temperature converter’s efficiency.<ref>
{{cite journal
{{cite journal
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|doi=10.1016/0039-6028(92)91335-9
|doi=10.1016/0039-6028(92)91335-9
}}</ref>
}}</ref>

== See also ==
[[Thermionic emission]]


==References==
==References==
{{Reflist}}
{{Reflist}}

==External links==
{{commons}}

[[Category:Condensed matter physics]]
[[Category:Electron beam]]

Latest revision as of 10:08, 20 July 2024

Not to be confused with Schottky defect.

The Schottky effect or field enhanced thermionic emission is a phenomenon in condensed matter physics named after Walter H. Schottky. In electron emission devices, especially electron guns, the thermionic electron emitter will be biased negative relative to its surroundings. This creates an electric field of magnitude F at the emitter surface. Without the field, the surface barrier seen by an escaping Fermi-level electron has height W equal to the local work-function. The electric field lowers the surface barrier by an amount ΔW, and increases the emission current. It can be modeled by a simple modification of the Richardson equation, by replacing W by (W − ΔW). This gives the equation[1][2]

where J is the emission current density, T is the temperature of the metal, W is the work function of the metal, k is the Boltzmann constant, qe is the Elementary charge, ε0 is the vacuum permittivity, and AG is the product of a universal constant A0 multiplied by a material-specific correction factor λR which is typically of order 0.5.

Schottky-emitter electron source of an Electron microscope

Electron emission that takes place in the field-and-temperature-regime where this modified equation applies is often called Schottky emission. This equation is relatively accurate for electric field strengths lower than about 108 V  m−1. For electric field strengths higher than 108 V m−1, so-called Fowler–Nordheim (FN) tunneling begins to contribute significant emission current. In this regime, the combined effects of field-enhanced thermionic and field emission can be modeled by the Murphy–Good equation for thermo-field (T-F) emission.[3] At even higher fields, FN tunneling becomes the dominant electron emission mechanism, and the emitter operates in the so-called "cold field electron emission (CFE)" regime.

Thermionic emission can also be enhanced by interaction with other forms of excitation such as light.[4] For example, excited Cs-vapours in thermionic converters form clusters of Cs-Rydberg matter which yield a decrease of collector emitting work function from 1.5 eV to 1.0–0.7 eV. Due to long-lived nature of Rydberg matter this low work function remains low which essentially increases the low-temperature converter’s efficiency.[5]

References

[edit]
  1. ^ Kiziroglou, M. E.; Li, X.; Zhukov, A. A.; De Groot, P. A. J.; De Groot, C. H. (2008). "Thermionic field emission at electrodeposited Ni-Si Schottky barriers" (PDF). Solid-State Electronics. 52 (7): 1032–1038. Bibcode:2008SSEle..52.1032K. doi:10.1016/j.sse.2008.03.002.
  2. ^ Orloff, J. (2008). "Schottky emission". Handbook of Charged Particle Optics (2nd ed.). CRC Press. pp. 5–6. ISBN 978-1-4200-4554-3.
  3. ^ Murphy, E. L.; Good, G. H. (1956). "Thermionic Emission, Field Emission, and the Transition Region". Physical Review. 102 (6): 1464–1473. Bibcode:1956PhRv..102.1464M. doi:10.1103/PhysRev.102.1464.
  4. ^ Mal'Shukov, A. G.; Chao, K. A. (2001). "Opto-Thermionic Refrigeration in Semiconductor Heterostructures". Physical Review Letters. 86 (24): 5570–5573. Bibcode:2001PhRvL..86.5570M. doi:10.1103/PhysRevLett.86.5570. PMID 11415303.
  5. ^ Svensson, R.; Holmlid, L. (1992). "Very low work function surfaces from condensed excited states: Rydber matter of cesium". Surface Science. 269/270: 695–699. Bibcode:1992SurSc.269..695S. doi:10.1016/0039-6028(92)91335-9.
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