Photoelectron surface escape probability of (Ga,In)As : Cs–O in the 0.9 to [inverted lazy s] 1.6 μm range

Fisher, Dennis G.; Enstrom, R. E.; Escher, J. S.; Williams, B. F.

doi:10.1063/1.1661817

Cited by 153 publications

(39 citation statements)

References 25 publications

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“…This strong dependence of yield on emission velocity supports the traditional emphasis on increasing the electron emission probability by minimizing the work function in NEA photocathodes. 28,29 However, even for cathodes with high emission velocities, emission yield can still be limited if recombination is more likely than emission at the front surface. Indeed, in typical NEA cathodes, emission probabilities (B in Eq.…”

Section: -mentioning

confidence: 99%

A model for emission yield from planar photocathodes based on photon-enhanced thermionic emission or negative-electron-affinity photoemission

Sahasrabuddhe

Schwede

Bargatin

et al. 2012

Journal of Applied Physics

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A general model is presented for electron emission yield from planar photocathodes that accounts for arbitrary cathode thickness and finite recombination velocities at both front and back surfaces. This treatment is applicable to negative electron affinity emitters as well as positive electron affinity cathodes, which have been predicted to be useful for energy conversion. The emission model is based on a simple one-dimensional steady-state diffusion treatment. The resulting relation for electron yield is used to model emission from thinfilm cathodes with material parameters similar to GaAs. Cathode thickness and recombination at the emissive surface are found to strongly affect emission yield from cathodes, yet the magnitude of the effect greatly depends upon the emission mechanism. A predictable optimal film thickness is found from a balance between optical absorption, surface recombination, and emission rate. Disciplines Mechanical EngineeringComments Sahasrabuddhe, K., Schwede, J., Bargatin, I., Jean, J., Howe, R., Shen, Z., & Melosh, N. (2012). A model for emission yield from planar photocathodes based on photon-enhanced thermionic emission or negativeelectron-affinity photoemission. Journal of Applied Physics, 112(9) A general model is presented for electron emission yield from planar photocathodes that accounts for arbitrary cathode thickness and finite recombination velocities at both front and back surfaces. This treatment is applicable to negative electron affinity emitters as well as positive electron affinity cathodes, which have been predicted to be useful for energy conversion. The emission model is based on a simple one-dimensional steady-state diffusion treatment. The resulting relation for electron yield is used to model emission from thin-film cathodes with material parameters similar to GaAs. Cathode thickness and recombination at the emissive surface are found to strongly affect emission yield from cathodes, yet the magnitude of the effect greatly depends upon the emission mechanism. A predictable optimal film thickness is found from a balance between optical absorption, surface recombination, and emission rate.

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Section: -mentioning

confidence: 99%

A model for emission yield from planar photocathodes based on photon-enhanced thermionic emission or negative-electron-affinity photoemission

Sahasrabuddhe

Schwede

Bargatin

et al. 2012

Journal of Applied Physics

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“…As proved by a series of activation experiments, the NEA formation mechanism for the GaAs-based photocathodes could be explained by the double dipole model [9,[21][22][23][24]. The proposed surface barrier profile consists of barriers I and II, arising from the Cs-O activation layer, as shown in Fig.…”

Section: Evaluation Of Photocathode Performancementioning

confidence: 93%

Differences in stability and repeatability between GaAs and GaAlAs photocathodes

Zhang

Feng

et al. 2016

Optics Communications

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“…According to semiconductor theory, the energy distribution of electrons thermalized in Γ valley or M-L valley is considered to satisfy Boltzmann distribution [7,8].…”

Section: Photoelectron Transportation To Cathode Surfacementioning

confidence: 99%

Study on photoemission mechanism for negative electron affinity GaN vacuum electron source

Qiao

Chang

Qian

et al. 2011

Phys. Status Solidi C

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The whole process including photoelectron excitation, transportation from bulk to surface and escape to vacuum by traversing surface barrier was analyzed in detail. Photoelectron excitation relates to the band structure of photocathode material and the absorption coefficient of the material. In the bulk of GaN photocathode, the photoelectrons mainly are transited into Γ valley first, when the energy is great enough, the photoelectrons can scatter into higher M‐L valley or A valley from Γ valley. The electrons excitated in conduction band will move from bulk to surface by diffusing or drifting. The diffuse length for GaN photocathode is about 3μm by calculating. After the thermal electrons of Γ valley move into surface band bend area, they will drift to the surface because of the electric field of band bend area. The transmission coefficient relates to the incident electron energy, the height and width of the surface potential. The quantum yield formulas of NEA GaN photocathode were gotten by solving the diffuse equation of non‐equilibrium carriers. (© 2012 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Photoelectron surface escape probability of (Ga,In)As : Cs–O in the 0.9 to [inverted lazy s] 1.6 μm range

Cited by 153 publications

References 25 publications

A model for emission yield from planar photocathodes based on photon-enhanced thermionic emission or negative-electron-affinity photoemission

A model for emission yield from planar photocathodes based on photon-enhanced thermionic emission or negative-electron-affinity photoemission

Differences in stability and repeatability between GaAs and GaAlAs photocathodes

Study on photoemission mechanism for negative electron affinity GaN vacuum electron source

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