Abstract
Solenoid Siberian snakes have successfully maintained polarization in particle rings below 1 GeV, but never in multi-GeV rings because the Lorentz contraction of a solenoid's integral B dl would require impractically long high-field solenoids. High energy rings, such as Brookhaven's 255 GeV Relativistic Heavy Ion Collider (RHIC), use only odd multiples of pairs of transverse B-field Siberian snakes directly opposite each other. When it became impractical to use a pair of Siberian Snakes in Fermilab's 120 GeV Main Injector, we searched for a new type of single Siberian snake, which should overcome all depolarizing resonances in the 8.9 - 120 GeV range. We found that one snake made of one 4-twist helix and 2 short dipoles could maintain the polarization. This snake design might also be used at other rings, such as Japan's 30 GeV J-PARC, the 12 - 24 GeV NICA proton-deuteron collider at JINR-Dubna, and perhaps RHIC's injector, the 25 GeV AGS.
Highlights
Solenoid Siberian snakes have successfully maintained polarization in particle rings below 1 GeV, but never in multi-GeV rings, because the spin rotation by a solenoid is inversely proportional to the beam momentum
Solenoid Siberian snakes are useful at low energies, but are difficult above a Rfew GeV due to the Lorentz contraction of a solenoid’s B · dl needed for the 180° spin rotation
We focus on finding a Siberian snake solution for rings with medium energies—too high for a single solenoid Siberian snake to be implemented and too low for pairs of transverse Siberian snakes to be practical
Summary
Solenoid Siberian snakes have successfully maintained polarization in particle rings below 1 GeV, but never in multi-GeV rings, because the spin rotation by a solenoid is inversely proportional to the beam momentum. High energy rings, such as Brookhaven’s 255 GeV Relativistic Heavy Ion Collider (RHIC), use only odd multiples of pairs of transverse B-field Siberian snakes directly opposite each other. In 1977 Derbenev and Kondratenko [3,4] proposed a clever way to overcome all depolarizing resonances by introducing a special sequence of magnets that would rotate each proton’s vertical spin component by 180° while leaving the proton’s orbital motion in the ring unchanged (optical transparency).
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