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Preservation and Control of Ion Polarization in MEIC

Spin resonance control in collider rings for proton and light ions to maintain high polarization levels, with a comparison of Figure-8 and racetrack structures.<br>

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Preservation and Control of Ion Polarization in MEIC

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  1. Preservation and Control ofIon Polarization in MEIC A.M. Kondratenko, M.A. Kondratenko Science and Technique Laboratory Zaryad, Novosibirsk, Russia Yu.N. Filatov Moscow Institute of Physics and Technology, Dolgoprydny, Russia V.S. Morozov, Ya.S. Derbenev, F. Lin, and Y. Zhang Jefferson Lab, Newport News, VA, USA MEIC Collaboration Meeting October 5-7, 2015

  2. Introduction Figure 8 or racetrack? Spin dynamics in a Figure-8 ring Polarization preservation during acceleration Polarization control in the collider ring Spin stability criterion andzero-integer spin resonance Initial spin tracking results Conclusions Outline

  3. Major MEIC ion complex components Polarization design requirements High polarization (~80%) of protons and light ions (d, 3He++, and possibly 6Li+++) Both longitudinal and transverse polarization orientations available at all IPs Sufficiently long polarization lifetime Spin flipping Ion Polarization Requirements Cooling Cooling to future high-energy collider ring SRF linac Ion source Booster 285 – 7062 MeV (accumulator ring) Medium-energy collider ring 8-100 GeV/c

  4. Spin tune (number of spin precession per turn) in a conventional ring A spin resonance occurs whenever the spin precession becomes synchronized with the frequency of spin perturbing fields Imperfection resonances due to alignment and field errors Intrinsic resonances due to betatron oscillations Coupling and higher-order resonances Spin Resonancesin Conventional Ring

  5. Racetrack booster Ep = 1.22 – 8 GeV, Ed = 2.03 – 8.16 GeV Protons ~13 imperfection resonances ~26 intrinsic resonances require full solenoidal Siberian snake, ~30 Tm Many higher-order resonances Deuterons 0 imperfection resonances 1 or 2 intrinsic resonances can be avoided Higher-order resonances can be accelerated through Racetrack collider ring Ep = 8 – 100 GeV, Ed = 8.16 – 100 GeV Protons ~175 imperfection resonances ~350 intrinsic resonances require two full dipole Siberian snakes, ~50 Tm Many higher-order resonances Deuterons 7 imperfection resonances can be crossed individually ~12 intrinsic resonances is a problem Many higher-order resonances ruin polarization and polarization lifetime Racetrack Resonances

  6. Figure-8 booster Same optics for all polarized and unpolarized ion beams Universally good and simple solution for polarization of any particles No restriction on the field ramp rate Additional arc bending angle of 150 Additional integrated dipole field BL = B ~ 70 Tm Extra space for quadrupoles, etc. Racetrack booster Proton & He3 polarization: OK Requires ~10 m long Siberian snake with ~30 Tm longitudinal field integral Snake field must ramp with energy Different optics for each ion species Allows one to shorten circumference by about 10 m Deuteron polarization: OK with fast ramp Can be handled with care Field ramp rate must be >~1 T/s Betatron tune jumps may be needed to cross spin resonances (this technique changes the optics during jumps) Figure-8 vs Racetrack Booster

  7. Figure 8 collider ring Same optics for all polarized and unpolarized ion beams Good for polarization Stable optics during acceleration and spin manipulation Additional arc bending angle of 163.4 Additional integrated dipole field BL ~ 950 Tm Extra space for quadrupoles, etc. Racetrack collider ring Proton polarization: probably OK but challenging Problem with optics stability especially at low energies Requires two full dipole Siberian snakes with a total field integral of ~50 Tm Figure-8 features can be preserved At low energies of ~8 GeV, the snakes introduce a significant tune shift (~0.2), which must be compensated; the tune shift changes nonlinearly with energy ~ -2 Deuteron polarization: realistically NO Cannot be preserved unless the ramp time to 100 GeV/c is less than ~1 s At the present acceleration rate, polarization is lost by ~10 GeV/c Even if polarization is preserved during acceleration, there is no guarantee of sufficient polarization lifetime; in fact, it will most likely be short. Figure-8 vs Racetrack Collider Ring

  8. Properties of a figure-8 structure Spin precessions in the two arcs are exactly cancelled In an ideal structure (without perturbations) all solutions are periodic The spin tune is zero independent of energy A figure-8 ring provides unique capabilities for polarization control It allows for stabilization and control of the polarization by small field integrals Spin rotators are compact, easily rampable and give no orbit distortion It eliminates depolarization problem during acceleration Spin tune remains constant for all ion species avoiding spin resonance crossing It provides efficient polarization control of any particles including deuterons It is currently the only practical way to accommodate polarized deuterons Electron quantum depolarization is reduced due to energy independent spin tune It makes possible ultra-high precision experiments with polarized beams It allows for a spin flipping system with a spin reversal time of ~1 s Spin Motion in a Figure-8 Ring

  9. Local spin rotator determines spin tune and local spin direction Polarization is stable if  >> w0 w0 is the zero-integer spin resonance strength B||L of only 3 Tm provides deuteron polarization stability up to 100 GeV A conventional ring at 100 GeV would require B||L of 1200 Tm or BL of 400 Tm Polarization Control Concept

  10. Pre-Acceleration & Spin Matching BIIL Booster beam from Linac to Collider Ring • Polarization in Booster stabilized and preserved by a single weak solenoid • 0.6Tm at 8GeV/c • d / p = 0.003 / 0.01 • Longitudinal polarization in the straight with the solenoid • Conventional 8GeV accelerators require B||L of ~30 Tm for protons and ~100 Tm for deuterons

  11. Booster lattice without solenoid Booster lattice with solenoid No correction needed Solenoid Matching in Booster solenoid

  12. “3D spin rotator” rotates the spin about any chosen direction in 3D and sets the stable polarization orientation nxcontrol module(constant radial orbit bump) z1=  nx/siny L 8 m x  1.6cmBymax= 3T nycontrol module(constant vertical orbit bump) z2=  ny/sinx L 8 m y  1.6cmBxmax= 3T nz control module z3=  nz zi, x, y – are the spin rotation angles of solenoid field, radial-field dipole and vertical-field dipole respectively. Polarization Control with 3D Spin Rotator x y z z Control of longitudinal (nz)spin component Control of vertical (ny)spin component Control of radial (nx)spin component IP

  13. Placement of the 3D spin rotator in the collider ring Integration of the 3D spin rotator into the collider ring’s lattice Seamless integration into virtually any lattice Polarization Control in the Collider Ring Spin-control solenoids Vertical-field dipoles Radial-field dipoles Lattice quadrupoles

  14. Momentum dependence of the solenoid strengths for deuterons, d = 10-4 Momentum dependence of the solenoid strengths for protons, p = 10-2 Solenoid Strengths Bz1 Bz2 Bz3 Bz1 Bz2 Bz3 Vertical Radial Longitudinal Vertical Radial Longitudinal

  15. Necessary for the physics program to reduce systematic uncertainties The universal 3D spin rotator can be used to flip the polarization Consider e.g. multiple polarization reversals at the IP at 100 GeV/c Polarization is flipped by reversing the fields of the solenoids in the radial and longitudinal spin control modules Polarization is preserved if The spin tune is kept constant during spin manipulation The rate of change of the polarization direction is slow compared to the spin precession rate > 0.1 ms for protons and > 10 ms for deuterons Spin Flipping

  16. The total zero-integer spin resonance strengthis composed of coherent part due to closed orbit excursions incoherent part due to transverse and longitudinal emittances Spin stability criterion the spin tune induced by the 3D spin rotator must significantly exceed the strength of the zero-integer spin resonance for proton beam for deuteron beam Zero-Integer Spin Resonance & Spin Stability Criterion

  17. The coherent part of zero-integer spin resonance induced by perturbing radial field hx()can be calculated using periodical response functionF(): F()is calculated from linear optics Perturbing radial fields arise, for example, due to dipole roll errors, vertical quads misalignments, etc. Such perturbing fields result in vertical closed orbit distortion Spin Response Function of Collider Ring

  18. Assuming certain rms vertical closed orbit distortion, we statistically calculate vertical orbit offset in the quadrupoles and resonance strength rms vertical closed orbit distortion for random misalignment of all quads Assuming that orbit distortion in the arcs < 100 m RMS Vertical Closed Orbit Distortion

  19. 2 T  2 m control solenoids allow setting p = 10-2 and d = 10-4 Sufficient for polarization stabilization and control Coherent Part of Resonance Strength • The coherent part of the zero-integer spin resonance strength is determined by closed orbit distortions. • Orbit distortion does not exceed 100 m

  20. Effect of higher-order resonances due to incoherent tune spread requires study similarly to the case of two Siberian snakes The incoherent part of the zero-integer spin resonance strength is determined by emittances of betatron and synchrotron oscillations and depends on magnetic lattice In an ideal lattice, the incoherent part is determined primarily by the emittance of vertical betatron oscillations Incoherent part of the resonance strength is determined by the second order and has vertical direction Assuming normalized vertical beam emittance of 0.07 m rad Incoherent Part of Resonance Strength

  21. Spin tracking using Zgoubi in collaboration with F. Meot of BNL MEIC lattice, no errors, 60 GeV/c proton, initial spin nz = 1, reference orbit Proton on one-sigma phase-space trajectories in both x and y Spin-Tracking Perfect Figure-8 Ring

  22. One arc dipole rolled by 0.2 mrad, no closed orbit correction After addition of a 1 spin rotator solenoid in the straight (s  310-3) Stabilization against Error Effects

  23. With 0.2 mrad dipole roll, no orbit correction, no spin rotator, 200103 turns After addition of a 5 spin rotator in the straight (s  1.410-2), 300103 turns Acceleration

  24. Schemes have been developed for MEIC based on the figure-8 design that eliminate resonant depolarization problem during acceleration allow polarization control by small fields without orbit perturbation provide for seamless integration of the polarization control into the ring lattice efficiently control the polarization of any particles including deuterons allow adjustment of any polarization at any orbital location allow spin manipulation during experiments make possible ultra-high precision experiments with polarized beams allow for straightforward adjustment of spin dynamics for any experimental needs Initial spin tracking results support the validity of the developed concepts Future work Systematic comparison of figure-8 and racetrack booster options Spin tracking to validate the statistical model and verify developed schemes Development of efficient numerical techniques for spin calculations Optimization of response function at the IP by tuning the lattice Spin flipping development Conclusions & Future Plans

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