Injector for the Electron Cooler

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Presentation transcript:

Injector for the Electron Cooler An overview of photoinjector options Fay Hannon Accelerator Scientist SRFR&D JLEIC Collaboration Meeting April 1-3, 2019

Would like to optimize the design with GPT Requirements From the injector 3.2nC ~5-8MeV 43.3MHz bunch frequency Magnetized with drift emittance 36um From cathode inside a solenoid Intrinsic emittance <19um Assumptions Gun voltage 400kV (DC) Magnetized beam Goal to preserve magnetization Want linear r, ρΦ Want to minimize the emittance in the cooling solenoid Thermal contributions Non linear dynamics Simulations are good for small, on axis beams Would like to optimize the design with GPT

How to define the objective/ what is ‘good’ Can think of the emittance as two contributions: Correlated r, ρΦ, from the magnetization Uncorrelated from thermal, space charge, RF In practice, correlated and uncorrelated emittance get messy Want correlated emittance to always be the correct value Want uncorrelated emittance to be small Small longitudinal emittance Small intrinsic energy spread Linear Uniform distribution in z

High Frequency Layout @ 952MHz Gun Single cell buncher / capture cavities 4 x two-cell booster 3rd harmonic (not shown)

High Frequency Optimization Results objectives

High Frequency Simulation Results 19-03-13-002 _13668std High Frequency Simulation Results

High Frequency Simulation Results Transverse Emittance Fit a slope to x, py data to get a correlated px and uncorrelated px

High Frequency Simulation Results Transverse phase space

Optimize with uniform distribution as an objective Trade off with magnetization (average is correct)

Low frequency solution – same layout @ 433MHz

Low Frequency Simulation Results

Low Frequency Simulation Results

High Frequency Simulation Results 19-03-12-002 _std54 High Frequency Simulation Results Transverse emittance

Comparison High Frequency Low Frequency KE [MeV] 6.8 8.5 z rms [mm] 4.03 3.36 Uncorrelated Emit [um] 6.4 11.5 Ez [keV mm] 24.4 28.6

Improve the Low Frequency Design Significant inverse correlation between Tcut and stduniform Significant correlation between XYrms and cnemixrms

Preliminary results Long bunch

Preliminary results

Outlook Improve the optimization More generations (this is ongoing) Quantify quality of magnetization Alternate layouts Laser shaping