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High Brightness Electron Source Development Brightness Limiting Phenomena Simulated bunch profile for 20pC and 80pC bunch charges from a realistic birefringent pulse-stacked laser profile. The onset of the virtual cathode instability (VCI) is apparent in the bunch lengthening and breakup. MK II DC Gun: Pushing brightness limits A new DC photogun is under construction @ Cornell. It will feature: •A segmented, shielded HV ceramic to reach higher voltage regimes. Adjustable cathode-anode gap, to allow precision control of the photocathode field, on which the onset of the VCI depends. •A genetically optimized electrode profile to provide highest brightness, subject to empirical breakdown voltage constraints. •A 6-D phase space measurement beamline, transverse emittance measurement, and ps-resolution deflecting cavity. Achieving Optimal Brightness • Genetically optimized 3D laser pulse profile to minimize space charge induced emittance growth. The MK II Gun will employ adaptive 3D laser pulse shaping to allow online optimization of emittance. Temporal shaping via birefringent crystal stacking Transverse – via truncated Gaussian Good light transmission, < 20% Photocathode development Gun development CsK2Sb photocathode development Sub-thermal emittance from GaAs cathodes I.V. Bazarov, L. Cultrera, S. Karkare, J. Maxson (for the ERL injector team) Presented at DOE Contractors’ Mtg, Annapolis, MD, August 22-23, 2011 Multi-Alkali Cathode Prep-chamber with vacuum suitcase 20mA, 8hr run Crater Light gray ~1.5 mm diameter Brown colored area ~4 mm diameter Photocathode film ~0.5 mm gap Damage on Si substrate after 20mA run SEM image of central damaged area Photocathode Diagnostics DIAGNOSTIC TECHNIQUES Auger Spectroscopy •LEED •Photoreflectance •Electron Energy Analyzers •Response time measurements •Work function measurement •XRF …. PREPARATION CHAMBERS •GaAs(Cs,F) •Alkali-Antimonide ERL INJECTOR DC GUN In Vacuum Connection In Vacuum Connection In Vacuum Connection In progress… Supported by DOE DE-SC0003965, NSF DMR- 0807731 Use of Genetic Algorithms to optimize gun geometry Varying Pierce angle (0 to 45) Varying gap (2 to 12 cm)

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High Brightness Electron Source Development. DIAGNOSTIC TECHNIQUES. PREPARATION CHAMBERS. A uger Spectroscopy LEED Photoreflectance Electron Energy Analyzers Response time measurements Work function measurement XRF …. GaAs ( Cs,F ) Alkali- Antimonide. - PowerPoint PPT Presentation

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Page 1: High Brightness Electron Source Development

High Brightness Electron Source Development

Brightness Limiting Phenomena

• Simulated bunch profile for 20pC and 80pC bunch charges from a realistic birefringent pulse-stacked laser profile.

• The onset of the virtual cathode instability (VCI) is apparent in the bunch lengthening and breakup.

MK II DC Gun: Pushing brightness limits• A new DC photogun is under construction @

Cornell. It will feature:• A segmented, shielded HV ceramic to reach

higher voltage regimes.• Adjustable cathode-anode gap, to allow

precision control of the photocathode field, on which the onset of the VCI depends.

• A genetically optimized electrode profile to provide highest brightness, subject to empirical breakdown voltage constraints.

• A 6-D phase space measurement beamline, transverse emittance measurement, and ps-resolution deflecting cavity.

Achieving Optimal Brightness

• Genetically optimized 3D laser pulse profile to minimize space charge induced emittance growth.

• The MK II Gun will employ adaptive 3D laser pulse shaping to allow online optimization of emittance.

• Temporal shaping via birefringent crystal stacking

• Transverse – via truncated Gaussian• Good light transmission, < 20% emittance change

from the optimum

Photocathode development

Gun development

CsK2Sb photocathode development Sub-thermal emittance from GaAs cathodes

I.V. Bazarov, L. Cultrera, S. Karkare, J. Maxson (for the ERL injector team)Presented at DOE Contractors’ Mtg, Annapolis, MD, August 22-23, 2011

Multi-Alkali Cathode Prep-chamber with vacuum suitcase

20mA, 8hr runCrater Light gray~1.5 mm diameter

Brown colored area~4 mm diameter

Photocathode film

~0.5 mm gap

Damage on Si substrate after 20mA run

SEM image of central damaged area

Photocathode Diagnostics DIAGNOSTIC TECHNIQUES

•Auger Spectroscopy

•LEED

•Photoreflectance

•Electron Energy Analyzers

•Response time measurements

•Work function measurement

•XRF….

PREPARATION CHAMBERS

•GaAs(Cs,F)•Alkali-Antimonide

•ERL INJECTOR•DC GUN

In Vacuum Connection

In Vacuum Connection

In Vacuum Connection

In progress…

Supported by DOE DE-SC0003965, NSF DMR-0807731

Use of Genetic Algorithms to optimize gun geometry

Varying Pierce angle (0 to 45)

Varying gap (2 to 12 cm)

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