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Oct. 6, 2006 1 Summary of the Polarisation Session J. Clarke, G. Moortgat-Pick, S. Riemann 10 November 2006, ECFA Workshop, Valencia.

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Presentation on theme: "Oct. 6, 2006 1 Summary of the Polarisation Session J. Clarke, G. Moortgat-Pick, S. Riemann 10 November 2006, ECFA Workshop, Valencia."— Presentation transcript:

1 Oct. 6, 2006 1 Summary of the Polarisation Session J. Clarke, G. Moortgat-Pick, S. Riemann 10 November 2006, ECFA Workshop, Valencia

2 Oct. 6 2006 2 Polarisation: Topics Polarimetry at the IP polarized e+ source:  GEANT4 with polarised processes:  E166 Status and results  target and radiation aspects Physics studies: Contactlike interactions radiative neutralino production Undulator source  30% e+ polarisation can be kept with spin rotators: Physics goal of P e+ ~30

3 Oct. 6 2006 3 Nello Paver: Identifying contactlike effective interactions Sensitivity to new physics ↔ deviations from predictions e+ polarisation enhances cross section  higher sensitivity (N~[1+P e+ P e- ]; smaller  P/P) Identification of new physics e+ polarisation is essential  smaller region of confusion g/   Z’, leptoquarks, …

4 Oct. 6 2006 4 Nello Paver: Identifying contactlike effective interactions

5 Oct. 6 2006 5 Olaf Kittel: Polarisation aspects in radiative neutralino production Discovery of R-parity conserving SUSY particles: indirect: missing energy direct: pair production of neutralinos, charginos, sleptons Process can be studied at ILC (not at LEP)

6 Oct. 6 2006 6 Olaf Kittel: Polarisation aspects in radiative neutralino production

7 Oct. 6 2006 7 Erez Reinherz-Aronis: Undulator-Based Production of Polarized Positrons e + Diag. γ Diag. e - Dump 46.6 GeV e - W Target 10 MeV γ Undulator Spectrometer e - to Dump Bending magnets preliminary

8 Oct. 6 2006 8 Erez Reinherz-Aronis: Results from E166 Analyzing power determined by simulations e+ polarisation between 50% and 90 % depending on e+ energy Preliminary

9 Oct. 6 2006 9 Andreas Schaelicke: Polarisation in GEANT4 Polarisation transfer - in the E166 experiment - Target studies Polarimetry at low energies Processes: - Pair-production - Bremsstrahlung - Compton scattering QED - Moller/Bhabha scattering - Positron annihilation in flight Use matrix formalism  diff. xs, asymmetry, polarisation, depolarisation and polarisation transfer

10 Oct. 6 2006 10 Andreas Schaelicke: Polarisation in GEANT4

11 Oct. 6 2006 11 A. Ushakov: Radiation and Target Aspects UBS: undulator based source (150 GeV e-, Ti alloy) CS: conventional source (6.2 GeV e-, W-Re target) Simulations done with FLUKA, SPECTER

12 Oct. 6 2006 12 Ken Moffeit et al.: Performance of 14 mrad Extraction Line at 500 GeV and 1 TeV

13 Oct. 6 2006 13 Ken Moffeit: Conclusions 0.5 TeV CMS Performance of Polarimeter Meets Goals 1 TeV CMS Performance of Polarimeter Meets Goals Large background from scattered synchrotron radiation photons at the Cherenkov Detector Concern about large beam losses for Low Power beam parameters

14 Oct. 6 2006 14 Core of beam within +-100microns has 48% of the beam. The polarization projection at the Compton IP is in good agreement with the luminosity weighted polarization at the e+e- interaction region. A precision measurement of +-0.25% will be possible. No beam losses from e+e- IR to Compton detector plane out of 17.6 million beam tracks for Normal ILC and Large-y beam parameter data sets. The Low Power beam parameter data set has losses of 1.1 * 10 -4. The collimator at z=164.25 meters needs to be designed. It absorbs the synchrotron radiation above the 0.75 mrad beam stay clear allowing the Cherenkov detector to begin at y~14 cm. Background from scattered synchrotron radiation occurs at the Cherenkov detector and will require careful design of the collimation and shielding. Ken Moffeit: Conclusions 14 mrad extraction line 0.5 TeV CMS Performance of Polarimeter Meets Goals

15 Oct. 6 2006 15 Core of beam within +-100microns has 43% of the beam. The large-y and low power parameter data sets have a lower Compton luminosity by a factor 2. The polarization projection at the Compton IP is in good agreement with the luminosity weighted polarization at the e+e- interaction region. A precision measurement of +-0.25% will be possible.  Beam losses of 1.8*10 -5 occur between the e+e- IR and the Compton detector plane for the Normal ILC beam parameter data set. Beam losses are also small but not negligible for the Large-y beam parameter data set. There are large losses of 0.53% of the beam for the Low Power beam parameter data set that will require insertion of a new collimator between the e+e- IR and the Compton detector plane or an increase in the beam stay clear from 0.75 mrad. The collimator at z=164.25 meters absorbs the synchrotron radiation above the 0.75 mrad beam stay clear allowing the Cherenkov detector to begin at y~14 cm. Background from scattered synchrotron radiation is very large at the Cherenkov detector and will require careful design of the collimation and shielding. 1 TeV CMS Ken Moffeit: 14 mrad extraction line Performance of Polarimeter Meets Goals Background from scattered synchrotron radiation photons at the Cherenkov Detector Concern about large beam losses for Low Power beam parameters

16 Oct. 6 2006 16 Jenny List: Detector development for High Energy Polarimetry

17 Oct. 6 2006 17 With the helical undulator e+ source we could have both beams polarised avarage e+ polarisation: ≈30%

18 Oct. 6 2006 18

19 Oct. 6 2006 19 With (80%, 30%) we expect a gain up to 2 compared to (80% ; 0%)

20 Oct. 6 2006 20 Summary & Conclusion  Group covers wide range of physics, production and measurement of e+ polarisation  With an undulator also the e+ beam is polarized!  we could have a polarized machine from the beginning!  To explore the polarisation spin rotators before (LTR) and after the DR (RTL) are needed (see SLAC-TN-05-045, EUROTeV-Report-2005-024-1) (spin-flip: pulse-to-pulse ?!)  Polarimetry of e- and e+ at the IP  Physics goal of 30% e+ polarisation: remember: first TESLA studies were done also with a 60/40 option; already 30% polarisation help to suppress background processes estimated improvement: factor ~2  details will be now considered

21 Oct. 6 2006 21 Layout of positron damping ring system showing the parallel spin rotation beam lines for randomly selecting positron polarization direction. A pair of kicker magnets is turned on between pulse-trains to deflect the beam to the spin rotation solenoids with negative B- field. space for spin rotators must be foreseen

22 Oct. 6 2006 22 To do !

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