1 / 26

SLAC Accelerator Development Program: SuperB

SLAC Accelerator Development Program: SuperB. Mike Sullivan OHEP Accelerator Development Review January 24-26, 2011. Outline. The SuperB design Where SLAC expertise has and can contribute Summary. SuperB is an e+e- collider running at the Upsilon 4S resonance

phoebe
Download Presentation

SLAC Accelerator Development Program: SuperB

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. SLAC Accelerator Development Program:SuperB Mike Sullivan OHEP Accelerator Development Review January 24-26, 2011

  2. Outline The SuperB design Where SLAC expertise has and can contribute Summary SLAC Accelerator Development Program Page 2

  3. SuperB is an e+e- collider running at the Upsilon 4S resonance The design luminosity is 11036 cm-2s-1 (50 times higher) This is achieved through: Ultra low-emittance beams Very small y* values Beam currents and bunch charge very similar to PEP-II and KEKB Bunch length similar to present day B-factories (very important for HOM issues) Magnetic crabbed waist at the IP Can also run at the Tau/Charm region with 1035 luminosity Electron beam is polarized SuperB Design

  4. e+e- Colliders

  5. SuperB Layout & Geometry IP 66 mrad HER arc LER arc LER arc HER arc e- e+ Circ = 1254 m RF

  6. Projected peak and integrated luminosity

  7. Superb Parameters

  8. SLAC Contributions Interaction Region design SLAC people have been involved in the design of the interaction region of SuperB since 2005. This has been with close cooperation from people at INFN Pisa and INFN Frascati as well as groups from the detector community. Lattice Some of the lattice topics we have studied are dynamic aperture, spin rotator insertions, geometric constraints and detector solenoid compensation. RF parameters, HOM studies and stability We have studied the RF parameters needed to sustain the required beam currents. They have also looked into how we can use the PEP-II RF systems in the SuperB design. Polarization We have put together a detailed design for the polarimeter needed to measure the longitudinal polarization of the stored electron beam.

  9. Interaction Region The design of the Interaction Region is one of the most difficult and crucial aspects of the collider A close association with the accelerator and the detector teams is a vital part of putting together a design that will work In close collaboration with INFN Frascati and INFN Pisa we have evolved an Interaction Region design that satisfies the accelerator and detector requirements

  10. SuperB Interaction Region Note the expanded left-hand scale m

  11. Interaction Region: Details One of the most challenging aspects of the SuperB IR design is the very low beta functions at the IP X* is 2.6 and 3.2 cm (PEP-II was 25-30 cm) 10 Y* is 0.25 and 0.21 mm (PEP-II was 8-12 mm) 50 Light source rings never squeeze the beam down this much The ILC design has similar values (2 cm and 0.4 mm) but that is a single pass machine These very low values force the final focusing magnets to be as close as possible to the collision point This puts all of the final focus magnets inside the detector

  12. Interaction Region: Details Other design constraints The detector needs as much total solid angle as the accelerator can give it (300 mrad cones – same as PEP-II) The detector beam pipe must be no larger than 10 mm radius in order to maximize the physics We have incorporated a special dual quadrupole design in order to meet the design requirements These magnets are super-conducting In addition, we have permanent magnets in the small region between the primary magnets and the junction of the beam pipes

  13. Some of the Main IR Design Issues Control of the SR backgrounds This drives much of the design as background rates can vary by orders of magnitude with seemingly small changes in design Control of the local HOM power Developing a cryostat design compatible with detector acceptance and magnet requirements Developing magnet designs that can perform to the demanding specs of the accelerator Developing a complete assembly and access plan

  14. Some IR Related Operational Issues Vibration control of the final focus elements It is vital to understand this issue and adopt adequate correction mechanisms. We have already started work on this issue and, in particular, with related aspects to the ILC IR design. Some present light source experience will help but we have to bring two very small beams into steady, reliable collision Luminosity measurement and maximization through beam position control SuperB will need a fast, accurate luminosity detector We have developed a preliminary design for a fast luminosity feedback (ala PEP-II system) to keep the beams in collision

  15. Lattice Work We have worked closely with the Italians (INFN Frascati) to develop a working lattice for the SuperB accelerator (2 examples) Spin rotator sections The spin rotator sections are an integral piece of the lattice and are also lose to the IP. The matching of the spin rotator sections with the other constraints concerning the lattice near the IP (crab waist, chromaticity correction, etc.) has been a complicated balancing act. Together we have developed a realistic lattice for this area. Solenoid compensation The compensation of the detector field is another complicated issue. The low emittance of the beams and the low coupling (The final focusing elements in the SuperB design are permanent magnets that are too close the IP to allow the detector field to be canceled by compensating solenoids. We have developed a scheme for solenoid compensation that involves rotating the PMs as well as compensating the detector field as much as possible and including skew quads and compensating solenoids located outside of the detector.

  16. Spin Rotator Section IP V12 Y-sext Crab Match & spin rotation X-sext • Similar layout as in HER except that matching section is shorter to provide space for spin rotator optics.

  17. Solenoid compensation Correctors within ±7.5 m of IP (symmetric relative to IP) Anti- solen LER H2 V1 Detector solenoid H1 QS1 V2 IP H2 QD0P QS1 H1 QF1 V1 Anti- solen QD0 V2 HER QS1 QSDY QSDPY QS2 QS3 QS4 IP CCY CCX ROT Skew quads in one half-IR QS1,QS2,QS3,QS4 – at zero dispersion QSDY,QSDPY – at non-zero dispersion [bxby]1/2

  18. RF, HOMs, beam stability A lot of work has gone into finding the RF parameters needed to support the 1-2A beam currents of the SuperB The RF systems of PEP-II have been selected by the SuperB project. These stations delivered half of the wall plug power to the beam, one of the most efficient high-current RF systems ever built. Minimizing the ring impedence and maximizing the cavity coupling are just a couple of the constraints used to optimize the design

  19. Phase transient We have also completed a very careful study of the phase transient induced by the ion gap in the ring current PEP-II experience has told us that an ion gap of at least 1-2% is necessary The phase transient is now an important issue since the collision has a large crossing angle (60-66 mrad) Control of the transient difference between the two beams has become an added constraint to the selection of beam current values and number of RF stations needed for each ring

  20. Polarization The SuperB design calls for a polarized electron beam This will significantly increase the physics potential of this accelerator We have found that the beam lifetime is too short for natural polarization to build up However, we can fill the ring from a polarized source and the beam will stay polarized as long as the depolarizing time is long enough One therefore has to stay away from depolarizing resonances

  21. Polarization vs Beam energy With a 90% polarized injected beam and a 3.5 min. ring lifetime we can have nearly 80% polarization if we stay near the peak

  22. Polarization Measurement Because we are constantly injecting polarized beam into the ring the measurement of the polarization of the beam becomes an interesting challenge We need to measure the polarization of each of the 978 beam bunches on a sub-minute time scale (the bunch frequency rate is over 200 MHz) The polarization measurement accuracy must be below 0.5% (at least as good as if not better than the measurement used for the SLC/SLD experiment) No one has done this

  23. Polarimeter The laser crosses the beam in a shallow vertical angle By adding a port in the beam pipe, we can also capture the gammas from the compton scatter We will use the bend magnets in the lattice as an energy spectrometer for the compton scattered electrons

  24. Workshops/collaborations The SuperB team has four workshops each year and this has been of enormous benefit to the design effort We are able to meet with our collaborators in Italy, exchange notes concerning design progress and brainstorm ideas to overcome newly uncovered issues Eight papers have come out of this effort over the last two years We have also been a main contributor to the writing up of the accelerator for the CDR in 2007 and for the update to the CDR (CDR2) completed last summer (2010)http://arxiv.org/find/all/1/all:+AND+SuperB+Accelerator/0/1/0/all/0/1

  25. Summary of what has been done The SuperB accelerator concept is quite exciting Making a collider using very low-emittance beams, very small * values, and high-currents (Similar to PEP-II currents) The crab waist concept is what gives this collider the ability to achieve nearly 100 times the luminosity of present day B-factories The simultaneous control of the low-emittance beams and the high-current effects on these beams will move accelerator technology into new territory The Interaction Region – one of the crucial aspects of the design – is an interesting balancing act of conflicting requirements. The design must cleanly mesh in order to maximize the chances of success.

  26. Conclusion SLAC and other US laboratories can make significant and lasting contributions to the SuperB accelerator while enriching and improving the accelerator program here in the U.S. The knowledge gained from getting this collider designed, built and operational will be invaluable for future accelerators Finally, the physics that will come from this collider is quite exciting!

More Related