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Explore the theory and simulation examples for correcting high-order aberrations in the SuperB Linear Energy Recovery (LER) chromatic section using finite sextupole lengths. Discover how small correction sextupoles can significantly increase dynamic aperture and reduce aberrations. This study investigates the recovery mechanism and predicts the strength and location of correction sextupoles based on theoretical models.
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SuperB Dynamic ApertureA.Bogomyagkov, E.Levichev, P.PiminovBINP, Novosibirsk16 June 2009, Perugia
Content:1. Correction of the high order aberrations in the – I transformation broken by the finite sextupole length 2. Theory 3. New approach4. Simulation example5. Conclusion
Sextupoles with finite length reduce DA (1) Vertical chromatic sextupoles in IR limit both vertical and horizontal dynamic apertures (vertical and coupling terms) (2) The main reason is the –I transformation break due to the non-zero length of the realistic sextupoles (3) For the kick sextupoles with the exactly tuned –I phase advance in between, the dynamic aperture is infinitely large
Pavel Piminov empirically -I recover (mechanism) • It was found that any distortion of the –I transformation can be recovered by an additional correction sextupole pair placed in some specific location relative to the main chromatic pair • The strength of the correction sextupoles is <10% of the main ones • The nature of this mechanism is not clear and further investigation is required(23 April 2009)
-I recover (results for the vertical direction) Correction sextupoles with the 5% strength and opposite sign restore the –I transformation in the vertical IR chromatic section and increase the dynamic aperture from DA 30 x 80 (x×y) toDA 90 x 550 (x×y)
Study of the –I transformation restore At this point we found that in the LER SuperB lattice an adjustment of the –I transformation is not perfect and in order to exclude this effect from the finite length sextupole study, we perform work below for the Tau-Charm Factory IR, which arrangement is close to the SuperB LER IR but with better tuning of –I. When the SuperB lattice will be completed (more or less) we shall do the DA optimization for it also.
DA vs. sextupole length Quadratic nonlinearity Cubic nonlinearity
Anton Bogomyagkov Theoretic background - binomial coefficient This solution is similar to the Lie series expansion but uses power series instead of the exponential ones. The solution is symplectic if not truncated.
Third order aberration of the sextupole pair Solution for the finite length sextupole pair –I Pure octupole terms Third order aberration of the thick sextupole pair with –I transformation in between is similar to the octupole term but not identical (signs and coefficients are different). So it could not be perfectly compensated by octupoles.
2+2 sextupoles (theory) l l If the sextupoles are located on the one side of quadrupole one set of coefficients can be zeroing and the other is reduced
main corr 8 cubic aberration terms are produced 2+2 sextupoles Piminov’s empiric config. –I Theory: 2 terms can be zero exactly and other 6 are reduced –I Bogomyagkov’s theory Predics better results Theory: 4 terms can be zero exactly and other 4 are reduced –I –I • Pair of the correction sextupoles increases the on-energy DA substantially. The strength of the corr. sexts is 3-10% of the main ones. • No quadratic aberration terms appear • No influence on the nonlinear dispersion
2+1 sextupoles 8 cubic aberration terms are produced –I –I Again 4 terms can be zero exactly and other 4 are reduced but small quadratic terms (~S2L) appear
The vertical chromatic section only Simulation examples for CTF Black: main sextupoles with –I but finite length Red: +correction sextupoles across the quad to the main ones (iniital approach): the vertical aberrations are cancelled but the coupling are remained Blue: +correction sextupoles on the side of the main ones: better cancellation of the aberration terms (vertical and coupling) Magenta: additional small numerical optimization
IR sextupoles optimization LEB DA with the IR sextupoles only (no arc sextupoles and other nonlinearities) Black: before optimization Red: after optimization
LER DA tune scan The tune point optimization should be done together with the beam-beam simulation and the luminosity/lifetime optimization Before the IR sextupoles optimization After the IR sextupoles optimization
Summary Sextupoles in the IR chromatic sections limit dynamic aperture due to the high aberrations (mainly the third order) of the –I transform Low strength (~3-10% of the main one) correction sextupole(s) can recover the dynamic aperture The theory predicting the strength and location of the correction sextupoles are developed Off-energy dynamic aperture ??? Correction octupoles instead of the correction sextupoles ???