1 / 31

FCAL and Super Belle

FCAL and Super Belle. Leszek Zawiejski. ■ Motivations ■ Requirement to improve super-Belle detector hermeticity ■ FCAL detectors and super-Belle proposal ■ Problems, questions – starting point for discussion on the proposal. FCAL Collaboration Meeting , May 07, 2008, Kraków.

tola
Download Presentation

FCAL and Super Belle

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. FCAL and Super Belle Leszek Zawiejski ■Motivations ■Requirement to improve super-Belle detector hermeticity ■FCAL detectors and super-Belle proposal ■Problems, questions – starting point for discussion on the proposal FCAL Collaboration Meeting , May 07, 2008, Kraków Slides on Belle results are based on M. Różańska, M. Yamauchi, M. Hazumi prezentations

  2. Motivations I High precision physics which can be studied with super-Belle detector II Test in running experiment, FCAL detectors before realisation of the ILC project

  3. B meson yield Super B Factory B Factory Mt. Tsukuba KEKB Belle

  4. Belle Experiment Beam crossing angle :22 mrad peak luminosity: 1.71 x 1034 cm-2 s-1 world record 1.3 million B B pairs/ day Total ~770106 B B pairs _ _

  5. Evidence for D0 mixing Observation of direct CP violation in B gp+p- Evidence for B gtn Observation of b g dg Decisive confirmation of Kobayashi-Maskawa model Evidence for direct CP violation in B g K+p- Measurements of CP violation in B gfKs, h’Ks etc. Observation of CP violation in B meson system Discovery of X(3872) Observation of B g K(*)ll Major achievements at Belle Belle collaboration 13 countries ~400 collaborators As of June 2007  # of papers : 219 # of citations: 9883 1. P Violation in B Decays 2. Fundamental SM Parameters (Complex Quark Couplings) 3. Beyond the SM (BSM) 4. Unanticipated New Particles

  6. Examples: B decays with missing energy - requirement to improve hermeticity of the Belle detector Examples:B  h , B+  + , Bo  D*-+ expected decay rates examples of SM amplitudes b c O(10-2) O(10-4) O(10-5)   W B0D*-+ Small hadronic effects; theoretically clean. b u   W B++ Sensistive to New Pysics W b s,d t B h   Z poorly known: multiple ’s in final states experimentaly difficult !

  7. Experimental Techniques B decay with missing energy e.g. B+K+  Btag Bsig reconstruct Btag signature: K + invisible K (4S)  at B-factories: e+e-(4S) BB Btag reconstruction: • BB event • which particles belong to Bsig • kinematical constraints on Bsig Two ways of Btag reconstruction: ■ Select Bsig candidate and check whether remaining particles are consistent with Bdecay („inclusive” Btag reconstruction) ■ Reconstruct Btag (in exclusive mode) and check whether remaining particles are consistent with Bsig(„exclusive” Btag reconstruction) Psig = - Ptag

  8. Bh(*) Expected BF’s in the SM: Flavor Changing Neutral Current process: Z-mediated electroweak penguin + box diagrams W t s,d b b s,d t t W W     Z J. H. Jeon et al., PL B 636, 270 (2006) Sensistive to New Physics in loops, e.g.: other weakly coupled particles:  DAMA b s,d CDMS b s,d h S S   possible window to light dark matter, not accessible in direct searches e.g. C. Bird et al., PRL 93, 201803 (2004)

  9. E = Ei - Ebeam Mbc = E2beam-(pi)2 Bh(*) - method h(*) = K*+,K*0,K+,K0, +,0,+,0, Reconstruct Btag in hadronic mode: Btag  signal signature: h(*) h(*) + nothing (4S)  788K B  MC 535 MBB EECL: residual energy in calorimeter for signal: EECL 0 B candidates background suppression:1.6 < ph(*) < 2.5 GeV/c Mbc[GeV/c2] suppress bc reject 2-body (eg. BK*)

  10. Bh(*) - results 535 MBB signal SM BF  20 hep-ex/0707.0138 submitted to PRL Theoretical predictions: C. Bird et al., PRL 93, 201803 (2004) K+ momentum 1.6 < p* < 2.5 GeV/c Nb= 20.0  4.0Nobs = 10 BF(B+ K+) < 1.4x10-5@90% CL Light dark matter? Can be searched in super-Belle B  K*  ( or )

  11. B purely leptonic B decay: W-mediated annihilation theoretically very clean,SM BF: b u B decay constant   W fB=0.2160.022 GeV from LQCD HPQCD Collab., PRL 95, 212001 (2005) providingfB is known Sensistive to Charged Higgs Heffects to branching fraction: b u H   mbtan+mccot mtan Decay amplitude  mb m tan2 W. S. Hou, PR D 48, 2342 (1993) Maria Rozanska for the Belle Collaboration

  12. B - results 449 MBB PRL 97, 251802 (2006) taking |Vub| = (4.39  0.33)×10-3 from HFAG Constraint on Charged Higgs (2HDM II) excluded rH

  13. BD(*) mbtan+mccot b c b c      W H mtan Theoretical tool: Heavy Quark Effective Theory (HQET) • Sensitive to extended Higgs sector • New Physics at tree level • Sensitive observables e.g.  polarization; possible O(1 ) effects Expected SM BF’s~O(10-2) inclusive BF(bc) = (2.48 0.26)% from LEP PDG 2007 • Y.Okada: CP violation & CKM; plenary talk at ICHEP06 • H-b-u vertex measured in B • H-b-c vertex measured in BD • H-b-t vertex measured in direct production by LHC.

  14. K.F Chen, C. Peng Forward Detector

  15. Forward Region

  16. K.F Chen, C. Peng

  17. FCAL detectors – candidates for use in Belle upgrade project? Pair Monitor

  18. LumiCal calorimeter EM Si/W calorimeter with 30 layers with the following thicknesses: Tungsten - 3.5 mm Silicon sensor - 0.32 mm Support - 0.6 mm Electronic space - 0.1 mm Inner radius of the active area : 80 mm Outer radius : 195 mm Sensor segmentation – 64 cylinders with 48 sectors in azimuth Calorimeter can be placed 2270 mm from IP The current design: Several ( 3 ) sensor layers can be used as tracker detector? Can an increase in granularity will be acceptable for FE electronics design as was prepared recently for ILC? Angular coverage from ~ 30 mrad to 80 mrad (ILD installation place)

  19. LumiCal extension : add silicon tracker (pad/pixel layers?

  20. (pCVD, GaAs, sCVD, radiation hard Si)

  21. Possible places for FCAL detectors at super-Belle The central region - Yoshuke talk or somewhere outside the central region ? FW 5.3 – 11.1 degree, BW 165.1 – 172.7 degree

  22. PROBLEMS - QUESTIONS Proposal to install FCAL detectors in super-Belle detector creates several problems and questions. Sensors&mechanics What sensors(silicon/diamond/GaAs) granularity seems to be sufficient?  How many layers?  What will be optimal type of the detector: calorimeter (tungsten/sensors) and tracker (with a few layers) or only tracker (pads, pixels layers)  How big energy deposit can be expected in sensors (shower, MIP’s)?  What power will be distributed by FE electronics – a way of cooling Radiation dose( during for example in year operation) ?  Place – how far from IP? Depends on type of the selected detector, accepted range for polar angle and background -outside the both sides of Belle detector, clamped on beam pipe? Monte Carlo (physics and detector ) studies can help to give answers for most of them FE electronics& readout What will be occupancy? Manpower and short time is a big problem: if the FE and readout electronics (ASIC,fanout) as designed for ILD detector can be used (with small modifications) for super-Belle project.

  23. Discussion on possible participation in super-Belle ? • How useful in realization of ours ILD tasks can be experience obtained by work of FCAL detectors in super-Belle experiment ? • Which FCAL groups (worked on the corresponding detector) can really be interested? • From realisation of the particular scientific tasks in Institutions working in FCAL, such group should became an official member of super- Belle collaboration • Timetable : what is exactly a death time for installation of FCAL detector (s) • inside super-Belle - 2012? It will be necessary to estimate more precisely • available menpower and cost. • Financial support – requested money, with help from super-Belle collaboration? • Such money should cover the build the prototypes, temporary work of specialists, • travel expences, staying in KEKB. • The possibility to get a big money from national financial institutions (polish) • are very limited.

  24. Strategy of super-Belle collaboration

  25. Roadmaps : KEKB Experiment + upgrade

  26. 2011 2012 2010 2009 2005 2006 2007 2008 GDE process RDR TDP 2 Tech, Design Phase 1 CLIC R&D EUROTeV and ILC construction commissioning LHC physics physics site selection EUDET

  27. Summary •  Super Belle Physics program will be very excited •  An increase of the detector hermeticity help in selection rare processes • FCAL detectors (with possible modifications), can play important role • in suplaying information on the missing energy (for selection the very clean • sample of events) • One can expect big problems with manpower, money, short timetable for realisation, formalities how to become the official member of super Belle collaboration •  Futher discussion on possibility to join the project is necessary

More Related