# Active bialkali photocathodes on free-standing graphene substrates

**Authors:** Hisato Yamaguchi, Fangze Liu, Jeffrey DeFazio, Claudia W. Narvaez, Villarrubia, Daniel Finkenstadt, Andrew Shabaev, Kevin L. Jensen, Vitaly, Pavlenko, Michael Mehl, Sam Lambrakos, Gautam Gupta, Aditya D. Mohite, Nathan, A. Moody

arXiv: 1703.00921 · 2017-03-06

## TL;DR

This study demonstrates the growth and characterization of high-efficiency bialkali photocathodes on free-standing graphene, showing potential for enhanced lifetime and stability in accelerator applications.

## Contribution

First successful integration of bialkali photocathodes on free-standing graphene substrates, enabling new insights into their spectral response and stability.

## Key findings

- Photocathodes on graphene show increased work function.
- Spectral response is comparable to traditional substrates.
- Enhanced stability and potential for longer lifetime.

## Abstract

The hexagonal structure of graphene gives rise to the property of gas impermeability, motivating its investigation for a new application: protection of semiconductor photocathodes in electron accelerators. These materials are extremely susceptible to degradation in efficiency through multiple mechanisms related to contamination from the local imperfect vacuum environment of the host photoinjector. Few-layer graphene has been predicted to permit a modified photoemission response of protected photocathode surfaces, and recent experiments of single-layer graphene on copper have begun to confirm these predictions for single crystal metallic photocathodes. Unlike metallic photoemitters, the integration of an ultra-thin graphene barrier film with conventional semiconductor photocathode growth processes is not straightforward. A first step toward addressing this challenge is the growth and characterization of technologically relevant, high quantum efficiency bialkali photocathodes grown on ultra-thin free-standing graphene substrates. Photocathode growth on free-standing graphene provides the opportunity to integrate these two materials and study their interaction. Specifically, spectral response features and photoemission stability of cathodes grown on graphene substrates are compared to those deposited on established substrates. In addition we observed an increase of work function for the graphene encapsulated bialkali photocathode surfaces, which is predicted by our calculations. The results provide a unique demonstration of bialkali photocathodes on free-standing substrates, and indicate promise towards our goal of fabricating high-performance graphene encapsulated photocathodes with enhanced lifetime for accelerator applications.

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Source: https://tomesphere.com/paper/1703.00921