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Advancing Particle Acceleration via Stimulated Emission of Radiation

Explore advanced development of PASER for enhanced energy gain, gradients, and understanding of new physics, with improved experimental design and theoretical exploration.

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Advancing Particle Acceleration via Stimulated Emission of Radiation

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  1. Advanced Development of Particle Acceleration by Stimulated Emission of Radiation (PASER) W. D. Kimura, L. Schächter, S. Banna ATF Users Meeting April 4-6, 2007

  2. Collaborators • Brookhaven National Laboratory (Accelerator Test Facility) - Marcus Babzien - Karl Kusche - Jangho Park - Igor Pavlishin - Igor Pogorelsky - Daniil Stolyarov - Vitaly Yakimenko • University of California, Los Angeles - David Cline - Xiaoping Ding - Lei Shao

  3. Outline • Background • Goals of Proposed Experiment • Improvements to Experiment Design and Procedure • Description of Experimental Apparatus • Phase I – High-Gradient Demonstration • Phase II – Staged PASER Demonstration • Proposed Schedule and Runtime Needs • Conclusions

  4. Background • Particle Acceleration by Stimulated Emission of Radiation (PASER) successfully demonstrated for first time at ATF in Proof-of-Principle (POP) experiment - PASER does not require multi-TW laser driver or subps e-beam bunch - Only requires train of microbunches with spacing equal to active medium transition wavelength - Requires no phase-matching to stage PASER sections • POP experiment can be improved upon in many ways - Hardware and operational improvements - Better control and diagnosing of experimental parameters - More extensive measurements and optimization of parameters - More thorough investigation of new physics related to PASER - More data to compare with model and theory

  5. Goals of Proposed Program • Primary experimental goals of Advanced PASER Development are: - Design and build improved PASER CO2 discharge system - Demonstrate much higher energy gain and acceleration gradients (target is >50 MeV/m) - Obtain more extensive data to characterize process, including investigating new physics associated with PASER effect - Demonstrate ease of staging process - Compare with model and theory • Primary theoretical goals are: - Investigate alternative active media, such as Ar+ plasma and solid- state media  Ar+ PASER operates at very low gas pressures  Solid-state PASER may be capable of ~1 GeV/m gradients and electrons travel in a vacuum - Develop theoretical basis for follow-on program

  6. Proposed Program Divided Into Two Phases • Phase I: - Design, build, and test at STI improved PASER gas chamber - Install improved PASER cell, plus diagnostics, on ATF beamline - Using existing IFEL, produce microbunch train to drive PASER - Perform extensive measurements to characterize and optimize system for maximum energy gain and gradient • Phase II: - Install second PASER discharge system - Measure characteristics of staged PASER system - Perform any additional measurements as needed

  7. Summary of Experiment Improvements

  8. Summary of Experiment Improvements (cont.)

  9. Possible Design for Improved PASER System • New PASER gas chamber designed to hold two PASER discharge assemblies • Gas scattering traveling through last half of chamber will not affect PASER energy gain – only reduces beam charge slightly

  10. Possible PASER Chamber Design

  11. Can Use Permanent-Magnet Quadrupoles for Triplets Before and After PASER Cell • STI manufactures PM quads • Compact design - Magnetic field tunable using motors to move magnets - Permits obtaining tight focus of beam into cell • Can also use hybrid focusing configuration - Use existing upstream electromagnet quads - Use single PM quad just before entrance to PASER cell

  12. Magnetic field plot Example of component layout Solenoid Around Electrode Can be Made With Permanent Magnets • Permanent magnet (PM) solenoid has advantages over electromagnet solenoid - More compact; does not require water-cooling or high-current power supply; is inherently stable; and can have stronger fields - STI has already performed preliminary magnetic analysis of PM solenoid for photocathode electron gun

  13. Measuring Gain of CO2 Discharge Gives Excited-State Energy Density • Use CO2 laser probe beam to measure gain versus discharge parameters • Will also use to optimize pumping efficiency • PASER theory predicts optimum energy density is a function of other parameters - Gain measurements important for verifying this dependence

  14. Optimum Energy Density Dependence Reveals Interesting New Physics • Optimum energy density of active medium (wact) shows oscillating dependence on number of microbunches M, but not beam size (Rb) - Implies collective effects of entire ensemble of electrons affects ability to extract energy from medium

  15. Summary of Major Phase I Tasks • Measure gain as function of CO2 gas mixture pressure, composition, and high-voltage settings at STI • Once installed at ATF, determine optimum tune for e-beam through cell - Adjust quads and solenoid - Maximize delivered charge • Use double-period STELLA undulator for operation of IFEL at 70 MeV - Adjust CO2 laser power to undulator to achieve desired modulation - May possibly utilize STELLA chicane to reduce drift space • Use CTR to monitor bunching efficiency • Perform PASER experiments - Vary number of microbunches by varying e-beam pulse length - Systematically scan over other parameters - Measure energy spectrum with and without discharge present

  16. Schematic of Staged PASER System • Second discharge system would be identical to first one • Note, staging requires no special positioning of second discharge with respect to first one

  17. Summary of Major Phase II Tasks • Use Phase I results to find optimum operating condition for second stage • Determine optimum e-beam tune through both stages - May primarily affect downstream e-beam optics, e.g., exit triplet - Again, aim for maximum charge throughput • Measure energy spectrum with and without second discharge on - Should see doubling of energy gain - Vary parameters to determine dependence - Compare with model predictions

  18. Advanced Concepts: Ar+ PASER • Advanced PASER concepts will be investigated in parallel with experimental effort and will focus on studying alternative active media • Argon ion laser active medium - Breakdown of medium less of issue because medium is already a plasma - Argon ion photons are 50 times more energetic than CO2 photons - Highest gain in pulsed argon lasers is at 476.5 nm at 20 – 30 mTorr - Pinch effect has been observed that might help enhance local excited-state density - Low pressure means may be able to use discharges similar to gas-filled capillaries (eliminates windows) • Challenge is making microbunch train with 476.5 nm bunch separation - Possibly use seeded FEL driven by Nd:YAG pumped dye laser  Creates microbunch train as by-product of FEL process  Approach being pursued at UCLA Neptune Lab in collaboration with STI - Use wire-mesh technique to generate custom microbunch train

  19. Advanced Concepts: Solid-State PASER • Use Nd:YAG rod as active medium with e-beam traveling through hole in center of rod - All scattering/breakdown effects eliminated because electrons travel through vacuum - Nd:YAG photons are 10 times more energetic than CO2 photons - Excited-state energy density is ~10 times higher - Hence, energy density may be 100 times larger → ~1 GeV/m possible - BUT, field from electrons does not appreciably penetrate into rod unless electrons are highly relativistic, i.e., 1 GeV • Challenge is making microbunch train with 1.06 mm bunch separation AND with 1 GeV energy - Possibly make train at low energy and accelerate in damping ring  Issues such as effects of coherent synchrotron radiation must be studied - In principle, can use wire-mesh technique, but 1 GeV beam must have low emittance

  20. Proposed Program Schedule and Runtime Needs • Estimate for runtime requirements - Phase I: 6 weeks - Phase II: 4 weeks

  21. Role of Collaborators • ATF staff responsible for - Generating microbunch train using STELLA undulator - Optimizing e-beam tune through system - Operation of CTR diagnostics • UCLA (Prof. Dave Cline) responsible for - Graduate and postdoc support - Similar role as during STELLA

  22. Conclusions • Advanced PASER Development program offers unique opportunity to investigate a new paradigm in advanced acceleration schemes - PASER is potentially a simpler scheme capable of comparable acceleration gradients as other advanced methods - If wire-mesh technique is used to make microbunch train, then this eliminates need for IFEL • PASER effect also has interesting physics - Collective e-beam effects on excited molecules affect energy exchange process - Opportunities to test better active media • There is a synergism between PASER, wire-mesh technique, STELLA, and inverse Cerenkov acceleration that is unique to the ATF

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