Superlattice photocathodes for accelerator-based polarized electron source applications

Author

Clendenin, J.E. ; Maruyama, T. ; Mulhollan, G.A. ; Mamaev, Yu.A. ; Subashiev, A.V. ; Yashin, Yu.P.

Author_Institution

Linear Accel. Center, Stanford Univ., CA, USA

Volume

3

fYear

1999

fDate

1999

Firstpage

1988

Abstract

A major improvement in the performance of the SLC was achieved with the introduction of thin strained-layer semiconductor crystals. After some optimization, polarizations of 75-85% became standard with lifetimes that were equal to or better than that of thick unstrained crystals. Other accelerators of polarized electrons, generally operating with a much higher duty factor, have now successfully utilized similar photocathodes. For future colliders, the principal remaining problem is the limit on the total charge that can be extracted in a time scale of 10 to 100 ns. In addition, higher polarization is critical for exploring new physics, especially supersymmetry. However, it appears that strained-layer crystals have reached the limit of their optimization. Today strained superlattice crystals are the most promising candidates for better performance

Keywords

electron accelerators; electron sources; linear colliders; optimisation; photocathodes; semiconductor superlattices; 10 to 100 ns; SLC; Stanford Linear Collider; accelerator-based polarized electron source; optimization; strained superlattice crystals; superlattice photocathodes; thin strained-layer semiconductor crystals; total charge limit; Acceleration; Capacitive sensors; Cathodes; Crystallization; Crystals; Electron sources; Gallium arsenide; Optical polarization; Physics; Superlattices;

fLanguage

English

Publisher

ieee

Conference_Titel

Particle Accelerator Conference, 1999. Proceedings of the 1999

Conference_Location

New York, NY

Print_ISBN

0-7803-5573-3

Type

conf

DOI

10.1109/PAC.1999.794337

Filename

794337