1 / 15

New AD Production Beam in the PSB

New AD Production Beam in the PSB. Until now , four h=1 bunches were ejected toward the PS in a single batch. New proposal (F. Pedersen): provide 5 bunches; either in a single or a double batch PS filling scheme.

amber
Download Presentation

New AD Production Beam in the PSB

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. New AD Production Beamin the PSB Until now, four h=1 bunches were ejected toward the PS in a single batch. New proposal (F. Pedersen): provide 5 bunches; either in a single or a double batch PS filling scheme. Aim: fill all the 5 available AD buckets instead of just 4 to increase the amount of delivered antiprotons. APC 25/4/08 Alfred Blas AB-RF-FB

  2. New AD Production Beamin the PSB • The production of 5 bunches in 2 PSB batches will not be discussed in this presentation as it doesn’t really affect the PSB operation. Note that the first batch in the PS, waiting for the second might experience a transverse blow-up due to space charge effects. This dilution would have a negative effect on the antiprotons production on the AD target that has not been quantified. • The production of 5 bunches in 1 PSB batch having 3 rings with a single bunch on h=1 and 1 ring with 2 bunches on h=2 will be discussed. APC 25/4/08 Alfred Blas AB-RF-FB

  3. New AD Production Beamin the PSB • 3 rings on h=1 and 1 ring on h=2 with the double intensity; all bunches should be identical but transversally, the multi-turn injection induces more emittance when the number of turns (intensity) is increased (normalized 2σ values: 55 μm instead of 30 μm in H and 50 μm instead of 20 μm in V; wire scanner measurements). This aspect and its impact on the final antiprotons production should be quantified (not done in this presentation) • Up to the flat-top all rings are operated the same way • At the flat-top only one ring would undergo a splitting process from 1 to 2 bunches (=> C02 voltage drop, C04 voltage increase, C16 blow-up, End dual harmonic loop, Start C04 phase loop, End C02 phase loop) • For the synchronization, a dedicated rf switch should provide the h2 reference to the h=2 ring. • For this operation 4 new timing pulses and 1 rf switching unit need to be supplied APC 25/4/08 Alfred Blas AB-RF-FB

  4. Present AD beam PSB extraction h=1 Trev = 572 ns 5 turns injected Tbunch = 215ns 8 kV / h = 1 1 kV h=2 @180o Blow-up active 400.1010 p/bunch emittance = 1.72 eV.s APC 25/4/08 Alfred Blas AB-RF-FB

  5. Present AD beam Blow-up cavity APC 25/4/08 Alfred Blas AB-RF-FB

  6. Present AD beam Synchronization phases APC 25/4/08 Alfred Blas AB-RF-FB

  7. Present AD beam Transfer line APC 25/4/08 Alfred Blas AB-RF-FB

  8. Present AD beam Transfer line For a proper filling of the h=8 buckets in the PS and for letting enough room for the recombination kicker rise time in between bunches, The bunch length should be limited to 191 ns (1-99 % rise time) BTKFA10 and BTKFA20 rise time (2-98)% = 88 ns (1-99)% = 95 ns APC 25/4/08 Alfred Blas AB-RF-FB

  9. Present CNGS h=2 beam Vh2 = 8 kV Vh1 = 0.5 kV 750.1010 p Tbunch = 183 ns Trf = 286 ns 375.1010 p/bunch Emittance = 1.61 eV.s APC 25/4/08 Alfred Blas AB-RF-FB

  10. Present CNGS h=2 beam APC 25/4/08 Alfred Blas AB-RF-FB

  11. How to create a h=2 matched beam? Firstthe blow-up should be such as to make each 2 bunches emittance equal to the h=1 bunch emittance. Compared to the present CNGS beam, the blow-up should be increase to obtain 7% more emittance. Second, the h=2 voltage should be set (Vh2 = 6.8 kV when Vh1 = 8 kV) so that all h=1 and h=2 bunches have the same length. APC 25/4/08 Alfred Blas AB-RF-FB

  12. Other possibility for the h=2 beam creation: Debunching and Recapture This operation would require the acceleration of a high intensity h=1 beam, with a strong blow-up (some more than for the CNGS beam) to obtain a total 3.4 eV.s beam emittance. This blow-up should be operated after the maximum Bdot (205 ms before the flat-top) to avoid losses due to bucket overfilling. On the flat top, the beam should be debunched and re-captured on h=2 up to the voltage of 6.8 kV. The beam should then be synchronized. All this should occur within the 40 ms of the flat-top. Using: for the debunching time constant (yellow book) One gets: tdb = 62 μs (quite small; to be checked) This gives us plenty of time for a proper adiabatic debunching and recapture Instabilities in the transverse plane with debunched beam to be checked! APC 25/4/08 Alfred Blas AB-RF-FB

  13. PS h=10 scenario Filling h=10 instead of h=8 buckets in the PS has the following impact: The bunch spacing in the transfer line becomes 229 ns (h=10 rf period) instead of 286 ns. Considering the kicker rise time of 95 ns, this leaves only 134 ns for the bunch length With h=1 at 8 kV and a bunch length of 134 ns, the beam emittance equals 0.75 eV.s instead of 1.72 eV.s in the h=8 scenario. This value is lower than the present 0.9 eV.s of the injected Linac beam. As presently the bunch length is 216 ns on the AD beam when the calculated limit is 191 ns, there seem to be a margin that would allow to create h=1 bunches without blow-up as the intensity is limited (4. 1012 p) Concerning the h=2 pair of bunches, there might be a lot of difficulties to achieve a bunch splitting at high intensity with such a little emittance. A stable splitting requires a well filled bucket, which can be obtained by lowering the rf voltages at the price of being faced to cavity parasitic beam loading effects. Note that there are no operational high intensity beam created without blow-up (robustness issues). Note that there should be a remaining h=1 voltage on the splitted beam to insure the required bunch spacing which is smaller than the rf h=2 period. The longitudinal matching issue with such a bucket should be considered. If the splitting cannot be achieved, the debunching-rebunching operation can be envisaged with the question marks invoked above and also the difficulty of having to add a h=1 phase locked voltage to create the proper bunch spacing. The synchronization would occurs on the h=1 component of the splitted beam. This has never been tried, but a-priori should not be a problem. APC 25/4/08 Alfred Blas AB-RF-FB

  14. Conclusion The required investment in the PSB to provide 5 bunches to the PS on h=8 and in a single batch should be low. The hardware changes require 3 man-day work and 0 CHF The setting-up time, from the operation point of view, should be limited (copy of AD for 3 rings and slightly modified CNGS settings for the remaining ring) Beam debunching and recapture on h=2 might be an alternative solution to the splitting although there are some question marks about the degrouping time and the transverse stability. Feeding the PS on h=10 present more operational uncertainties related to rf gymnastics with a low emittance beam. These aspects need more study before this operation type can be proposed. The AD target efficiency goes down with increased transverse emittances and the higher the intensity in one ring, the higher the transverse emittance due to the multi-turn injection process. This aspect has not been checked yet. Thanks to M. Chanel, T. Eriksson, A. Findlay, S. Hancock for sharing their knowledge APC 25/4/08 Alfred Blas AB-RF-FB

  15. Annex: slide from M. Chanel For the AD beam (total 1.6 1013 on target), the PSB should accelerate 450 1010/ring. To add one bunch more on target, one PSB ring should accelerate 900 1010at least. The beam density increases from 38 to 50 1010/mm.mrad(+32%)and the emittances from (eh,ev)=(16,7.5) to (24,14) pmm.mrad. If all the particles are on target, it will increase the production by 8% for a 20% increase of beam intensity! APC 25/4/08 Alfred Blas AB-RF-FB

More Related