Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes

Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes

Electron beams are essential tools in modern science. They are ubiquitous in fields ranging from microscopy to the creation of coherent ultra-fast X-rays to lithography. To keep pace with demand, electron beam brightness must be continually increased. One of the main strategic aims of the Center for...

Full description

Bibliographic Details
Main Authors: Gerard Lawler, Kunal Sanwalka, Yumeng Zhuang, Victor Yu, Timo Paschen, River Robles, Oliver Williams, Yusuke Sakai, Brian Naranjo, James Rosenzweig
Format: Article
Language:English
Published: MDPI AG 2019-10-01
Series:Instruments
Subjects:
high brightness
electron source
field emission cathode
electron optics
cathode diagnostics
Online Access:https://www.mdpi.com/2410-390X/3/4/57
id doaj-e2bb6854fc7d42158742e9e316431089
record_format Article
spelling doaj-e2bb6854fc7d42158742e9e3164310892020-11-25T01:56:45ZengMDPI AGInstruments2410-390X2019-10-01345710.3390/instruments3040057instruments3040057Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission CathodesGerard Lawler0Kunal Sanwalka1Yumeng Zhuang2Victor Yu3Timo Paschen4River Robles5Oliver Williams6Yusuke Sakai7Brian Naranjo8James Rosenzweig9Department of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics, Friedrich-Alexander-Universit at Erlangen-Nurnberg (FAU), 91054 Erlangen, GermanyDepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USADepartment of Physics & Astronomy, UCLA, Los Angeles, CA 90028, USAElectron beams are essential tools in modern science. They are ubiquitous in fields ranging from microscopy to the creation of coherent ultra-fast X-rays to lithography. To keep pace with demand, electron beam brightness must be continually increased. One of the main strategic aims of the Center for Bright Beams (CBB), a National Science Foundation Science and Technology Center, is to increase brightness from photocathodes by two orders of magnitude. Improving the state-of-the-art for photoemission-based cathodes is one possibility. Several factors have led to an alternative design becoming an increasing necessity; the nanoscale structure. Field emission sources from nano-tips would be an ideal candidate were it not for their low current and damage threshold. A 1-dimensional extended nano-fabricated blade, i.e., a projected tip, can solve the problems inherent in both designs. The novel geometry has been demonstrated to produce extremely high brightness electron beam bunches and is significantly more robust and easier to manufacture than traditional photocathodes. Theory indicates electron emission up to keV energies. We thus present a system of diagnostics capable of analyzing the cathodes and assessing their viability. The diagnostics are designed to measure the electron spectrum up to keV energies, with sub meV resolution at <100 eV, mean transverse energy (MTE), emission uniformity, and cathode lifetime. We also report preliminary data on total extracted charge and maximum detectable electron energy with a simplified retarding field spectrometer.https://www.mdpi.com/2410-390X/3/4/57high brightnesselectron sourcefield emission cathodeelectron opticscathode diagnostics
collection DOAJ
language English
format Article
sources DOAJ
author Gerard Lawler
Kunal Sanwalka
Yumeng Zhuang
Victor Yu
Timo Paschen
River Robles
Oliver Williams
Yusuke Sakai
Brian Naranjo
James Rosenzweig
spellingShingle Gerard Lawler
Kunal Sanwalka
Yumeng Zhuang
Victor Yu
Timo Paschen
River Robles
Oliver Williams
Yusuke Sakai
Brian Naranjo
James Rosenzweig
Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes
Instruments
high brightness
electron source
field emission cathode
electron optics
cathode diagnostics
author_facet Gerard Lawler
Kunal Sanwalka
Yumeng Zhuang
Victor Yu
Timo Paschen
River Robles
Oliver Williams
Yusuke Sakai
Brian Naranjo
James Rosenzweig
author_sort Gerard Lawler
title Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes
title_short Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes
title_full Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes
title_fullStr Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes
title_full_unstemmed Electron Diagnostics for Extreme High Brightness Nano-Blade Field Emission Cathodes
title_sort electron diagnostics for extreme high brightness nano-blade field emission cathodes
publisher MDPI AG
series Instruments
issn 2410-390X
publishDate 2019-10-01
description Electron beams are essential tools in modern science. They are ubiquitous in fields ranging from microscopy to the creation of coherent ultra-fast X-rays to lithography. To keep pace with demand, electron beam brightness must be continually increased. One of the main strategic aims of the Center for Bright Beams (CBB), a National Science Foundation Science and Technology Center, is to increase brightness from photocathodes by two orders of magnitude. Improving the state-of-the-art for photoemission-based cathodes is one possibility. Several factors have led to an alternative design becoming an increasing necessity; the nanoscale structure. Field emission sources from nano-tips would be an ideal candidate were it not for their low current and damage threshold. A 1-dimensional extended nano-fabricated blade, i.e., a projected tip, can solve the problems inherent in both designs. The novel geometry has been demonstrated to produce extremely high brightness electron beam bunches and is significantly more robust and easier to manufacture than traditional photocathodes. Theory indicates electron emission up to keV energies. We thus present a system of diagnostics capable of analyzing the cathodes and assessing their viability. The diagnostics are designed to measure the electron spectrum up to keV energies, with sub meV resolution at <100 eV, mean transverse energy (MTE), emission uniformity, and cathode lifetime. We also report preliminary data on total extracted charge and maximum detectable electron energy with a simplified retarding field spectrometer.
topic high brightness
electron source
field emission cathode
electron optics
cathode diagnostics
url https://www.mdpi.com/2410-390X/3/4/57
work_keys_str_mv AT gerardlawler electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT kunalsanwalka electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT yumengzhuang electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT victoryu electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT timopaschen electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT riverrobles electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT oliverwilliams electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT yusukesakai electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT briannaranjo electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
AT jamesrosenzweig electrondiagnosticsforextremehighbrightnessnanobladefieldemissioncathodes
_version_ 1724978099608616960

Similar Items