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Injection to IOTA ring. Sergey Antipov, University of Chicago Fermilab Mentor: Sergei Nagaitsev. Integrable Optics Test Accelerator. P roof-of-principle experiment designed to demonstrate a concept of integrable accelerator lattice with highly non-linear optics.
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Injection to IOTA ring Sergey Antipov, University of Chicago FermilabMentor: Sergei Nagaitsev
Integrable Optics Test Accelerator • Proof-of-principle experiment designed to demonstrate a concept of integrable accelerator lattice with highly non-linear optics. • Demonstrate that huge nonlinear tune shifts can be achieved in a realistic accelerator design • My part: Design injection part of the ring and conduct first-stage experiments with non-linear optics
Injection section Lattice functions RMS beam size Optics designed by Gene Kafka
Optics is flexible Integrable Optics Optical Stochastic Cooling Optics designed by Gene Kafka
Summary of requirements • Single turn injection (No storage needed) • Should suit both integrable optics and optical stochastic cooling lattice designs • Injection kicker should be able to work for experiments • Proton injection? • Components: • Beam transmission line • Septum magnet • Fast kicker • Local orbit bump (if any) Injection procedure. Orbit bump is not shown
Single turn injection Kick:
Plan • Choose a design of injection magnet • Determines separation of orbits • Locations of magnet and kicker • Beta-functions • Kick angle • Design of kicker • Voltage • Transmission line • Should provide matching (β, α, D, D`)
Septum magnet • Place particles onto the correct trajectory • Bend ~ 15 deg. • Installed in high-beta region to reduce the kick • Options: • Can be DC (heating might be an issue) or pulsed (stability might be an issue) • Current sheet isolation or Lambertson
Septum design Current sheet isolation Lambertson Injection in horizontal plane Possible problems with field leakage Septum thickness – determined by max current density Pulsed device Injection in vertical plane A bigger (more expensive) device Septum thickness Can be DC
DC Lambertson septum • DC offers higher stability than pulsed devices • Lambertson septum has simpler design • Gap increased to fit for proton injection • Power consumption ~ 1.5 kW • Beam separation:Septum thickness 2mm +thickness of vacuum chambers +reserve -> ~ 10 mm
Fast kicker • Stripline • Length: • Separation of plates: • Bend angle: • Pulse duration: • Will be used for nonlinear optics experiment –>must have enough power for them • At least 8 mrad • Should have 50 Ω wave impedance • Can fit inside quadrupole magnets
Want wide kicker plates • Greater field in the center • More homogenous field • Probably, need to separate H and V kickers Opening angle 80 deg Vertical E-field as a function of radius for different θ.Applied voltage 30 kV.Green – 45, blue – 60, red – 80 deg.
Up to 30-40 kV can be achieved with solid stateshort pulse generators • Prices on products of Directed Energy • Would require HV DC power supply (cost not included)
Minimizing Vkick • Vary kicker lengthand position, position of septum, number, strength and position of dipole correctors • Constraints: • Min separation of beams – 10 mm • Particles should not hit kicker plates, 2 mm reserve • Orbit of circulating beam should be no closer than 6σ to physical aperture • Lengths: septum – 50 cm, correctors – 15 cm • Length of kicker < 2 m • integrated field of dipole correctors – 10 kGs-cm
Option 1. Septum in the center of straight section Option 2. Septum between pairs of quads
Requirements to short pulse generators • Need 4 pulsers • ~ 100 % reserve for integrableoptics experiments • Final choice of pulse generators willdetermine design of the kicker
What else can be done? • Reduce aperture at septum • Allow to inject with 0 anglewithout hitting kicker plates • 1 cm does not affect admittance • Reduce kicker length • No orbit correction? • 1 sec synchrotron damping time • Same kick needed
Current and future activity • Contacted manufacturers about quotes for high power short pulse generators • Choice of a generator determines final kicker design • Electric design of stripline kicker • Design of septum magnet • Finalize positions of injection magnet and kicker • Beam line
Simulating field in kicker • SCT EM Studio • Need: • 50 Ohm wave impedance • E < 50 kV/cm at any point