Cs-O$_2$-Li as enhanced NEA surface layer with increased lifetime for GaAs photocathodes

Maximilian Herbert, Tobias Eggert, Joachim Enders, Markus Engart, Yuliya Fritzsche, Maximilian Meier, Julian Schulze, Vincent Wende
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Abstract

GaAs-based photocathodes are the only viable source capable of providing spin-polarized electrons for accelerator applications. This type of photocathode requires a thin surface layer, in order to achieve negative electron affinity (NEA) for efficient photo-emission. However, this layer is vulnerable to environmental and operational effects, leading to a decay of the quantum efficiency $\eta$ characterized by a decay constant or lifetime $\tau$. In order to increase $\tau$, additional agents can be introduced during the activation procedure to improve the chemical robustness of the surface layer. This paper presents the results of recent research on Li as enhancement agent for photocathode activation using Cs and O$_2$, forming Cs-O$_2$-Li as enhanced NEA layer. Measurements yielded an increase in lifetime by a factor of up to 19 $\pm$ 2 and an increase in extracted charge by a factor of up to 16.5 $\pm$ 2.4, without significant reduction of $\eta$. This performance is equal to or better than that reported for other enhanced NEA layers so far.
将 Cs-O$_2$-Li 作为增强型 NEA 表面层,提高砷化镓光电阴极的使用寿命
基于砷化镓的光电阴极是唯一能够为加速器应用提供旋转极化电子的可行光源。这种类型的光电阴极需要一个较薄的表面层,以实现负电子亲和力(NEA),从而实现高效光发射。为了增加$\tau$,可以在活化过程中引入附加剂来改善表面层的化学稳健性。本文介绍了最近关于使用铯和O$_2$形成Cs-O$_2$-Li增强负电子亲和层作为光电阴极活化增强剂的研究成果。测量结果表明,寿命增加了 19 倍,提取电荷增加了 16.5 倍,而$/ea$没有显著减少。这一性能等同于或优于迄今报道的其他增强型核能源层的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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