“Beam Losses” Christian Carli PSB H - Injection Review, 9 th November 2011 Several topics more or less related to beam losses, a study still somewhat at.

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Presentation transcript:

“Beam Losses” Christian Carli PSB H - Injection Review, 9 th November 2011 Several topics more or less related to beam losses, a study still somewhat at the starting phase (resources) Outline: Beam Losses and Activation to be expected Losses to be expected (vague estimates) Activation at present and in future PSB Acceptance and Apertures Smaller “BeamScope” Window Apertures and acceptance Very preliminary study on Collimation Injection steering Summary and questions

Losses to be expected – first 5 ms "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 Partially stripped and unstripped H 0 and H - : 1% to 2 % (see previous presentations) During injection and chicane fall: ~5% (from Diploma thesis of M. Scholz)  Perturbations of lattice due to new injection  Compensation with additional quadrupolar components (trims on lattice quadrupoles) Blue: perfect compensation Green and red: too high (+10%) and too low (-10%) compensation settings Accumulated versus number of times (“slow” chicane with active compensation)

Losses to expected - extrapolations from present Circulating beam intensity as function of time for User NTOF (one high intensity bunch for the PS)  About 15 % or protons lost "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 Intensity > protons ejected

Losses to expected - extrapolations from present Intensity versus time for a high intensity cycle for ISOLDE  Normal loss for the two rings with highest initial intensities?  Say about 15 % of protons lost at low energy "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 Intensity

Losses to expected - comparison with present “Low energy” losses  Losses at present with Linac2: For high intensity beams, about 55% of the protons from Linac2 are lost (most at injection at 50 MeV) Losses to generate one high intensity bunch with protons: protons  Losses to be expected with Linac4 (from simple extrapolations) About 20 % (5 to 10% during injection and chicane fall plus 10 to 15% during low energy part) (disregarding effect of higher injection energy on Losses to generate one high intensity bunch with protons: protons  Effect on activation assuming 10 times higher activation per lost proton at 160 MeV About a factor three more activation “High energy” losses  Linac4 aims at increasing the intensity by a bit less than a factor 2  Larger energies with upgrade (2.0 GeV instead of 1.4 GeV)  Expect a factor two more activation and integrated dose per year to equipment Expect an increase of PSB activation and annual dose with Linac4 "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011

SB Radiation Survey on 23/11/2010 and 38 hours after the end of operation (M. Widorski) Impact of Linac4 (apart possible average increase)  Reduction of the spike in section 1 (from conv. multiturn injection)  Increase downstream from BeamScope window (possible shifted into section?) Beam Losses to be expected BR.BHZ51 BR.BHZ52 BR.QDE5 “BeamScope” window (determines PSB aceptance) Spike related to “BeamScope” "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011

PSB Acceptance and Apertures - Smaller “BeamScope” Window With 160 MeV injection energy, maximum normalized emittance possible at injection increased by almost a factor two Aim with Linac4: similar normalized emittances available at ejection  Is this still valid with a 2 GeV upgrade? (slight) decrease of physical emittance with higher energy Decrease of the machine acceptance possible  Installation of a window similar to “BeamScope” window  Loss of large amplitude protons at low energy (less radiation and activation) and not after acceleration in the ejection channel  Profit from larger acceptance in rest of the ring for a (rough) collimation system  Injection foil less in machine acceptance after fall of injection painting bump (only chicane fall moves foil definitely out of acceptance) "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011

PSB Acceptance and Apertures – Apertures and acceptance D inj = 0 m, 35 mm painting bump Colors:  Blue:  p/p =  violet:  p/p =  Red:  p/p = Solid lines: start of injection Dashed: largest emittances for given momentum offset Black: maximum beam position after painting bump fall "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011

PSB Acceptance and Apertures – Apertures and acceptance D inj = -1.4 m (matched), 50 mm painting bump, window shifted by 10 mm Colors:  Blue:  p/p =  violet:  p/p =  Red:  p/p = Solid lines: start of injection Dashed: largest emittances for given momentum offset Black: maximum beam position after painting bump fall "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011

Very preliminary study on collimation First investigations on collimation assuming (LHC like) multiturn approach (by doctoral student P. Jackson)  Profit from acceptance margin; collimation may reduce PSB acceptance by almost a factor two  Proton interacting with collimator still makes many turns and several interactions with collimation Efficiency (simplified model) for vertical loss at 160 MeV (from a presentation by P. Jackson)  Very thin primary collimators (otherwise no multiturn behaviour), heating an issue Around 1995, first study by T.Trenkler and H.Schonauer on single turn system Study should start with better understanding of present situation  NO RESOURCES AVAILABLE SO FAR TO STUDY COLLIMATION IN PSB LINE AND RING "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 Absorption mainly after first interaction (model realistic?) for high Z primary

"Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 PSB Injection Steering Update of the study from 2008 taking voluntary offsets introduced since then into account Principle  Two steerers/plane and ring in last part of the line to adjust position and angle at the injection septum (individual for all four rings) Shifting second dipole upstream increases deflections needed DHZ/DVT50 Injection (reference) DHZ/DVT70 l2l2 l1l1

"Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 PSB Injection Steering: Analysis of present situation Currents programmed for DHZ/DVT 50 and 70 (for both planes, all four rings, different USERs, in 2008 and 2011) converted into position and angle Scatter plots of position and angle (left) and integrated strengths (right)  Data from 2008: different colour for USERs LHC25A, NORMGPS and LHCINDIV  Data from 2011: Two USERS, all plotted in gray  Stars and diamonds for horizontal and vertical plane (similar picture in both planes)  Contours describe estimated tuning range required Up to ±12 mm and ±2.4 mrad (ratio is ~5m, i.e. the betatron function) around origin … Smaller contour (not used further) … if mean correction can be done upstream  Required strength well below maximum possible strengths

"Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011 PSB Injection Steering: Analysis Extrapolation to Linac4 Beam rigidity increased by a factor ~1.9 DHZ/DVT70 moved upstream by ~2 m (precise position to be determined)  Assumption l D50 = 7.27 m and l D70 = 3.14 m Offset of ~10 mm at the injection point required  10 mm in horizontal with reference position of incoming beam moved towards PSB center  Up to 10 mm in vertical to generate required emittance (no active painting) Maximum strength of 130 Gm and 160 Gm to have some safety margin  DHZ/DVT50 position further upstream increases required strengths

Summary and Questions Many of the topics presented at a very preliminary stage (resources) Preliminary estimates on machine activation and annual dose to be expected  Increase (not dramatic) to be expected without mitigation measure  Can losses be an issue for equipments (accumulated doses..) and people (activation)? PSB acceptance and apertures  Machine acceptance reduction only a proposal  Should we implement it? … would require a serious study and design (too late anyhow?) Collimation  Conclusion of very preliminary study: multiturn approach looks not feasible  Priority/time-scale to study another scheme? ….. first understand present beam losses, then try to design a collimation system  Study of collimation in the injection line? ….. discussed, but never studied, to protect sensible devices like Injection steering  New steerers to be constructed and installed  Approach and requested strength appropriate? "Beam Losses" PSB 160 MeV H- Injection Review, 9th November 2011