Photoemission studies of yttrium photocathodes by using the visible radiation

The present work reports on Yttrium based photocathodes. A Yttrium (Y) thin film is deposited via pulsed laser deposition (PLD) on the copper (Cu) back flange of a radio frequency (rf) gun for photocathode application. Because of a lower work function with respect to Cu, Y photocathodes are particul...

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Published in	Physical review. Accelerators and beams Vol. 23; no. 12; p. 123401
Main Authors	Scifo, J., Lorusso, A., Chiadroni, E., Cinquegrana, P., Dabagov, S., Danailov, M., Demidovich, A., Ferrario, M., Garzella, D., Giribono, A., Hampai, D., Perrone, A., Trovò, M.
Format	Journal Article
Language	English
Published	College Park American Physical Society 01.12.2020
Subjects	Copper Emittance Lasers Photocathodes Photoelectric emission Photoelectrons Pulsed laser deposition Pulsed lasers Quantum efficiency Sapphire Thin films Titanium Work functions Yttrium
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Abstract	The present work reports on Yttrium based photocathodes. A Yttrium (Y) thin film is deposited via pulsed laser deposition (PLD) on the copper (Cu) back flange of a radio frequency (rf) gun for photocathode application. Because of a lower work function with respect to Cu, Y photocathodes are particularly appealing for the possibility to illuminate them with visible laser pulses, with the advantage of a higher energy per pulse, paving the way to high repetition rate photoinjectors, driven by conventional laser sources. In addition, working atλ∼400nmthe small energy difference between the Y work function (about 3 eV) and the laser photon energy reduces the contribution of the intrinsic emittance of the material. Photoelectrons, emitted by the thin film Y photocathode driven by the second harmonic of a Ti:Sapphire laser, have been characterized in terms of quantum efficiency and transverse emittance. Results have been compared with the theoretical ones obtained by the three-step model of Spicer for metallic photocathodes.
AbstractList	The present work reports on Yttrium based photocathodes. A Yttrium (Y) thin film is deposited via pulsed laser deposition (PLD) on the copper (Cu) back flange of a radio frequency (rf) gun for photocathode application. Because of a lower work function with respect to Cu, Y photocathodes are particularly appealing for the possibility to illuminate them with visible laser pulses, with the advantage of a higher energy per pulse, paving the way to high repetition rate photoinjectors, driven by conventional laser sources. In addition, working at λ∼400 nm the small energy difference between the Y work function (about 3 eV) and the laser photon energy reduces the contribution of the intrinsic emittance of the material. Photoelectrons, emitted by the thin film Y photocathode driven by the second harmonic of a Ti:Sapphire laser, have been characterized in terms of quantum efficiency and transverse emittance. Results have been compared with the theoretical ones obtained by the three-step model of Spicer for metallic photocathodes. The present work reports on Yttrium based photocathodes. A Yttrium (Y) thin film is deposited via pulsed laser deposition (PLD) on the copper (Cu) back flange of a radio frequency (rf) gun for photocathode application. Because of a lower work function with respect to Cu, Y photocathodes are particularly appealing for the possibility to illuminate them with visible laser pulses, with the advantage of a higher energy per pulse, paving the way to high repetition rate photoinjectors, driven by conventional laser sources. In addition, working atλ∼400nmthe small energy difference between the Y work function (about 3 eV) and the laser photon energy reduces the contribution of the intrinsic emittance of the material. Photoelectrons, emitted by the thin film Y photocathode driven by the second harmonic of a Ti:Sapphire laser, have been characterized in terms of quantum efficiency and transverse emittance. Results have been compared with the theoretical ones obtained by the three-step model of Spicer for metallic photocathodes.
ArticleNumber	123401
Author	Chiadroni, E. Danailov, M. Cinquegrana, P. Scifo, J. Giribono, A. Perrone, A. Lorusso, A. Garzella, D. Hampai, D. Trovò, M. Dabagov, S. Ferrario, M. Demidovich, A.
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SubjectTerms	Copper Emittance Lasers Photocathodes Photoelectric emission Photoelectrons Pulsed laser deposition Pulsed lasers Quantum efficiency Sapphire Thin films Titanium Work functions Yttrium
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Title	Photoemission studies of yttrium photocathodes by using the visible radiation
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