Analysis of Beamstrahlung Pairs

1. Analysis of Beamstrahlung Pairs Christian Grah ECFA Workshop Vienna, November 14-17, 2005

2. Outline • Very Forward Calorimetry • Fast luminosity monitoring • Analyzing pairs from beamstrahlung with BeamCal • Pair distributions in different geometries and magnetic field configurations • Summary & outlook Ch.Grah: Analysis of Beamstrahlung Pairs

3. Very Forward Region LumiCal: 26 < θ < 82 mrad BeamCal: 4 < θ < 28 mrad PhotoCal: 100 < θ < 400 μrad Ch.Grah: Analysis of Beamstrahlung Pairs

4. Very Forward Calorimeters • LumiCal: • Precise measurement of the luminosity by using Bhabha events (very high mechanical precision needed). • Extend coverage of the ILC detector. • Photocal • Beam diagnostics from beamstrahlung photons. • BeamCal: • Detection of electrons/photons at low angle. • Beam diagnostics from beamstrahlung electrons/positron pairs. • Shielding of Inner Detector. Ch.Grah: Analysis of Beamstrahlung Pairs

5. BeamCal: Beam Diagnosticsand Fast Luminosity Monitoring e+ e- e+e-pairs from beamstrahlung are deflected into the BeamCal Deposited energy from pairs at z = +365 (no B-field, TESLA parameters) • 15000 e+e- per BX => 10 – 20 TeV • ~ 10 MGy per year • “fast” => O(μs) • Direct photons for q< 400 mrad (PhotoCal) Ch.Grah: Analysis of Beamstrahlung Pairs

6. BeamCal: W-Diamond Sandwich Space for electronics Length = 30 X0 (3.5mm W + .5mm diamond sensor) ~ 15 000 channels ~1.5/2 cm < R < ~10(+2) cm Ch.Grah: Analysis of Beamstrahlung Pairs

7. Fast Luminosity Monitoring • Pair signal included into the fast feedback system. Luminosity development during first 600 bunches of a bunch-train. Ltotal = L(1-600) + L(550600)*(2820-600)/50 L improvement for 500 GeV G.White QMUL/SLAC RHUL & Snowmass presentation position and angle scan Ch.Grah: Analysis of Beamstrahlung Pairs

8. Beamstrahlung Pairs • Observables (examples): • total energy • first radial moment • thrust value • angular spread • E(ring ≥ 4) / Etot • E / N • l/r, u/d, f/b asymmetries • Beam parameters • σx, σy, σz and Δσx, Δσy, Δσz • xoffset • yoffset • Δx offset • Δy offset • x-waist shift • y-waist shift • Bunch rotation • N particles/bunch • (Banana shape) detector: realistic segmentation, ideal resolution, bunch by bunch resolution Ch.Grah: Analysis of Beamstrahlung Pairs

9. Analysis Concept Taylor Matrix Observables Observables Δ BeamPar nom • Beam Parameters • determine collision • creation of beamstr. • creation of e+e- pairs • guinea-pig • (D.Schulte) • Observables • characterize energy distributions in detectors • FORTRAN • analysis program (A.Stahl) 1st order Taylor-Exp. Solve by matrix inversion (Moore-Penrose Inverse) = + * Ch.Grah: Analysis of Beamstrahlung Pairs

10. Slopes parametrization (polynomial) 1 point = 1 bunch crossing by guinea-pig slope at nom. value  taylor coefficient i,j observable j [au] beam parameter i [au] Ch.Grah: Analysis of Beamstrahlung Pairs

11. Multi Parameter Analysis σx Δσx σy Δσy σz Δσz 0.3 % 0.4 % 3.4 % 9.5 % 1.4 % 0.8 % 1.5 % 0.9 % 0.3 % 0.4 % 3.5 % 11 % 0.9 % 1.0 % 11 % 24 % 5.7 % 24 % 1.6 % 1.9 % 1.8 % 1.1 % 16 % 27 % 3.2 % 2.1 % Ch.Grah: Analysis of Beamstrahlung Pairs

12. Moving to 20mrad crossing anglewith DID Coordinate system • Boost the generated pairs (GuineaPig) according to crossing angle. • Shift center of detector to the outgoing beam. • New segmentation of the detector and blind area for the incoming beam. • Use a simplified implementation of DID field. (B.Parker & A.Seryi) Ch.Grah: Analysis of Beamstrahlung Pairs

13. Old Geometry for 20mrad Applied the algorithm to the old 20mrad geometry, using TESLA parameters. Multi Parameter Analysis has also been done. PRELIMINARY! Ch.Grah: Analysis of Beamstrahlung Pairs

14. 20mrad crossing angle – old geometry Sketch of BeamCal geometry. Projection of LumiCal‘s inner radius. Energy deposited in LumiCal from pairs. Here: ILC nom. beam parameters Ch.Grah: Analysis of Beamstrahlung Pairs

15. Backgrounds • 20mrad DID • backscattering from pairs hitting the LumiCal edge Background simulations by Karsten Buesser. 20mrad solenoid Ch.Grah: Analysis of Beamstrahlung Pairs

16. First try to fix Situation improved but still a factor of ~5 worse than in the 2mrad case. Larger increase of the aperture is necessary, which will increase the background from backscattering from the BeamCal... Study is ongoing. • Changed geometry: • increased aperture of LumiCal by 3 cm • increased outer radius of BeamCal by 3 cm • increased apertures in between accordingly Hits in TPC Ch.Grah: Analysis of Beamstrahlung Pairs

17. Options for 20mrad under investigation 20mrad AntiDID 14mrad AntiDID DID, large aperture (Ri(LumiCal) > 13cm) DID, small aperture Ch.Grah: Analysis of Beamstrahlung Pairs

18. Summary • A fast luminosity signal can significantly increase the luminosity. • Analyzing beamstrahlung grants access to many beam parameters. • Promising results also for 20mrad case. • Single and Multiparameter analysis is feasible. • The Very Forward region design for large crossing angles needs: • The AntiDID field configuration OR • A massively increased aperture (LumiCal’s inner radius). Ch.Grah: Analysis of Beamstrahlung Pairs

19. Outlook • The beam diagnostics, which was based upon a FORTRAN/HBOOK code is now being ported to a GEANT4 based simulation, including: • Usage of b field map files. • Realistic detector response. • Fast shower parameterization. • Optimization of observables. • Studies on the new 20mrad geometry are ongoing. Ch.Grah: Analysis of Beamstrahlung Pairs