The Project Francesco Forti, INFN and University, Pisa Commissione Scientifica Nazionale 1 30 Marzo 2009 Status update.

Presentazione sul tema: "The Project Francesco Forti, INFN and University, Pisa Commissione Scientifica Nazionale 1 30 Marzo 2009 Status update."— Transcript della presentazione:

1 The Project Francesco Forti, INFN and University, Pisa Commissione Scientifica Nazionale 1 30 Marzo 2009 Status update

2 30 marzo 2009F.Forti SuperB Status CSN12 SuperB Physics Physics at a Super Flavor Factory collecting 50 – 100 ab -1 is exciting: –Precision measurements allowing to detect discrepancies from the standard model Theoretical precision allows (or will allow) this in many channels –Rare decay measurements –Lepton flavour violation –Possibility to run at tau/charm threshold –Polarized e- beam   CPV, EDM, g-2 See for example: –The Discovery Potential of a Super B Factory (Slac-R-709) –Letter of Intent for KEK Super B Factory (KEK Report 2004-4 ) –Physics at Super B Factory (hep-ex/0406071) –SuperB report (hep-ex/0512235) –SuperB CDR (INFN/AE-07/02, SLAC-R-856, LAL 07-15) –Many documents available at the URL : www.pi.infn.it/SuperB © by Ciuchini

3 30 marzo 2009F.Forti SuperB Status CSN13 Luminosity [10 28 cm -2 s -1 ]  y=18mm, Pw_angle=0.6  y=9mm, Pw_angle=1.9

4 Best two fills Luminosity vs Current Product

5 The Process

6 30 marzo 2009F.Forti SuperB Status CSN16 The SuperB Process (Courtesy of M. Biagini) www.pi.infn.it/SuperB 2005200620072008 2 th Joint Japan-US SuperB-Factory Workshop, Hawaii, US International SuperB Study Group formed 1 st SuperB Workshop, LNF, Italy International SuperB Steering Committee established 2 nd SuperB Workshop, LNF, Italy 3 rd SuperB Workshop, SLAC, US 1 st Accelerator retreat, SLAC, US 4 th SuperB Workshop, Villa Mondragone, Italy SuperB meeting, Daresbury,UK CDR writing started CDR published 5 th SuperB Workshop in Paris, France CDR presented to INFN Management CDR presented to ECFA International Review Committee setup 2 th Accelerator retreat, SLAC, US 1 st IRC meeting, LNF, Italy 2nd IRC meeting, Rome, Italy Accelerator test started at DA  NE, LNF, Italy 6 th Physics retreat at Valencia, Spain Detector R&D workshop, SLAC,US ICFA08 Workshop at BINP, Russia 7 th SuperB Meeting in Elba, Italy – IRC REPORT Mini MAC 4 9 113 4 6 9 11 1235 5 7 7 9 11 121 2 3 4 4 6 7 10 12. Month CERN strategy group presentation 2 nd Meeting with ECFA ECFA Report INFN Approval of SuperB TDR phase arxiv.org/abs/0709.0451

7 30 marzo 2009F.Forti SuperB Status CSN17 Reviews INFN Internation Review Comm –John Dainton – UK/Daresbury, chair –Jacques Lefrancois – F/Orsay –Antonio Masiero – I/Padova –Rolf Heuer – D/ Desy –Daniel Schulte – CERN –Abe Seiden – USA/UCSC –Young-Kee Kim – USA/FNAL –Hiroaki Aihara – Japan/Tokyo + Tatsuya Nakada (RECFA) + Steve Myers – accel expert Report released May 2008 recommend strongly continuation of work for 10 36 cm -2 s -1 asymmetric e + e - collider RECFA Committee (2008) –Tatsuya Nakada –Yanis Karyotakis –Frank Linde –Bernhard Spaan CERN strategy group (2008) -chair Steinar Stapnes OK: seek government approval DOE Particle Physics Project Prioritization Panel (P5) Report released May 2008 Recommend significant US Participation in offshore flavour factory in the intermediate funding scenario Mini Machine Advisory Commitee –Klaus Balewski (DESY) –John Corlett (LBNL) –Jonathan Dorfan (SLAC, Chair) –Tom Himel (SLAC/ DESY) –Claudio Pellegrini (UCLA) –Daniel Schulte (CERN) –Ferdi Willeke (BNL) –Andy Wolski (Liverpool) –Frank Zimmermann (CERN) First meeting in July 08 No glaring showstoppers Form a management structure

8 30 marzo 2009F.Forti SuperB Status CSN18 Comments on reviews Link to meetings and reports: http://www.pi.infn.it/Super B/reviews Dainton committee  Mini MAC Very exciting project -- Committee is exhilarated by the challenge Physics requirement of 10**36 cm-2 sec-1 or 75 ab-1/5yr is very demanding Committee considers the SINGLE MOST ESSENTIAL ingredient for moving forward is the formation of a sanctioned management structure which formally incorporates a dedicated machine design team. The team members must have the strong support of their home institutions to work on the design. The team needs a designated leader, who is as close to full time as is possible The Committee sees no glaring showstoppers wrt achieving the design performance. However, in several key areas, more work is needed before the design can be blessed

9 30 marzo 2009F.Forti SuperB Status CSN19 ECFA report *We consider that flavour physics should be seen as an important part of the European research programme of elementary particle physics, complementary to physics provided by the energy frontier experiments. For the coming ~5 years, LHCb will do this job in the b and c quark sectors. To follow-up this progress, collecting 50 ab−1 or more at Υ(4S) energy with e+e− storage rings by the end of the next decade would be a significant milestone, if this can be realised at a moderate cost. *The INFN Super Flavour Factory project team proposes a novel scheme […]. This idea of obtaining a high luminosity with tiny beam spots at the collision point based on very small emittance beams and crab waist collisions could revolutionize the design of the future colliders. Therefore, westrongly support the R&D effort to see if such a machine can really be built. *The current tests at DAFNE are promising and we would like to congratulate the team for this impressive achievement. However, a substantial amount of work is still required for producing a Technical Design Report, […] *Given the complexity of the project, we feel that a clear plan containing realistic technical milestones and resource requirements together with a strategy how to obtain them is needed as a necessary condition for an approval of the project. *Such a plan should aim at obtaining an integrated luminosity of significantly more than 50 ab−1 by not much later than the end of the next decade. Given the very ambitious time scale, a clear decision taking process must be established soon.

10 30 marzo 2009F.Forti SuperB Status CSN110 INFN Il 19 dicembre il consiglio direttivo ha approvato la stesura del TDR per SuperB – progetto speciale SuperB TDR La regione Lazio contribuirà con un fondo di ricerca di 5M€/anno per tre anni per la preparazione dei Technical Design Report –Ingegneri, progettazione ingegneria civile, finalizzazione progetto di macchina –Possibilità di contratti per personale dedicato –Una parte di R&D per acceleratore e rivelatore –Ancora da capire i dettagli gestionali L’INFN contribuirà sul bilancio ordinario –Bilanci dei gruppi in Commissione I –Fondi per TDR acceleratore

11 30 marzo 2009F.Forti SuperB Status CSN111 SuperB Organization Chart for TDR Phase 10/03/2008 Accelerator R&D, Engineering and Construction Accelerator Technical Board Detector R&D, Engineering and Construction Detector Technical Board Site computing system, offline Infrastructure, Facilities, Services Oversight Board International Board of Representatives R&D + Preparatory Studies Linac Magnets Mech. Design IR/Final Focus Vacuum Transfer Lines Alignment Diagnostics Polarization Parameters Optics Beam Dynamics RF/Feedback Fluid Supplies Damping Rings Control System Power Supplies Rad. Protection Tunnel, power, water, utilities, ……… Computing Accelerator Consortium Detector Collaboration Local Infrastructure SVT DCH PID EMC IFR Magnet Offline Computing Online Computing Electronics Trigger DAQ Rad. Monitor Lum. Monitor MDI Computing Model Mini-MAC Mini-DET Mini-COMP SuperB Project Office - TDR Phase Director Deputy Director 1 Deputy Director 2 Deputy Director 3 Administrative and scientific staff Marcello Giorgi David Hitlin David Leith Guy Wormser M.Morandin F.Forti, B.Ratcliff S.Tomassini J.Seeman, P.Raimondi

12 30 marzo 2009F.Forti SuperB Status CSN112 Prossimi passi 1.Report(s) necessari per l’approvazione iniziale del progetto da parte del governo Tempistica dettata dalla politica e dalla necessità di far partire gli scavi al più presto E prima che RP finisca come presidente Fine 2009: Technical Description dell’acceleratore Accelerator Site Study Un qualche “Design Report” su: rivelatore, computing, physics 2.Report(s) necessari per una review tecnica completa e per l’approvazione delle spese Technical Design Report/Engineering Design Report Acceleratore, Sito, Rivelatore: Fine 2010 Computing: potrebbe arrivare 1-2 anni dopo.

13 30 marzo 2009F.Forti SuperB Status CSN113 Workshops 2009 Orsay 15-19 febbraio 2009 –Partenza ufficiale delle attività per il Technical Design Report Warwick (Physics) 15-20 aprile 2009 Roma, giugno 2009 –Possibile incontro con il Ministro, Confindustria SLAC, 5-9 ottobre 2009 LNF, 1-5 dicembre 2009

14 30 marzo 2009F.Forti SuperB Status CSN114 Detector (Proto) technical board Detector Coordinators – B.Ratcliff, F. Forti Technical Coordinator – W.Wisnieswki SVT – G. Rizzo DCH – G. Finocchiaro PID – N.Arnaud, J.Va’vra EMC – D.Hitlin  C.Cecchi, F.Porter IFR – R.Calabrese Magnet – W.Wisniewski Electronics, Trigger, DAQ – D. Breton, U. Marconi Online/DAQ – Offline SW – –Simulation coordinator – D.Brown –Fast simulation – M. Rama –Full Simulation – F. Bianchi Rad monitor – Lumi monitor – Background simulation – M.Boscolo, E.Paoloni Machine Detector Interface – Structure being setup inside systems

15 30 marzo 2009F.Forti SuperB Status CSN115 Finanziamento della regione Lazio Attraverso un protocollo di intesa approvato all’ultimo direttivo. Temi: Vedremo alla fine gli item specifici

16 The Detector Maggiori dettagli su attività di interesse CSN1: http://agenda.infn.it/conferenceDisplay.py?confId=1363

17 30 marzo 2009F.Forti SuperB Status CSN117 Detector Babar and Belle designs have proven to be very effective for B- Factory physics –Follow the same ideas for SuperB detector –Try to reuse same components as much as possible Main issues –Machine backgrounds – somewhat larger than in Babar/Belle –Beam energy asymmetry – a bit smaller –Strong interaction with machine design A SuperB detector is possible with today’s technology –Baseline is reusing large (expensive) parts of Babar –Quartz bars of the DIRC –Barrel EMC CsI(Tl) crystal and mechanical structure –Superconducting coil and flux return yoke. Some areas require moderate R&D and engineering developments to improve performance –Small beam pipe technology –Thin silicon pixel detector for first layer –Drift chamber CF mechanical structure, gas and cell size –Photon detection for DIRC quartz bars –Forward PID system (TOF or focusing RICH) –Forward calorimeter crystals (LSO) –Minos-style scintillator for Instrumented flux return –Electronics and trigger – need to revise Bfactory “½-track” trigger style –Computing – large data amount More details in: –www.pi.infn.it/SuperB/node/159 - SuperB Italy Meeting on detector R&Dwww.pi.infn.it/SuperB/node/159 –indico.lal.in2p3.fr/conferenceDisplay.py?co nfId=167 – Paris workshop (May 9-11)indico.lal.in2p3.fr/conferenceDisplay.py?co nfId=167 –https://agenda.infn.it/conferenceDisplay.p y?confId=163 – Review (Nov 12-13)https://agenda.infn.it/conferenceDisplay.p y?confId=163

18 30 marzo 2009F.Forti SuperB Status CSN118 Detector Layout – Reuse parts of Babar BASELINE OPTION

19 30 marzo 2009F.Forti SuperB Status CSN119 Silicon Vertex Tracker The Babar SVT technology is adequate for R > 3cm: –use design similar to Babar SVT Layer0 is subject to large backround and needs to be extremely thin: –More than 5MHz/cm 2, 1MRad/yr, < 0.5%X 0 –Striplets option: mature technology, not so robust against background. Marginal with background rate higher than ~ 5 MHz/cm 2 Moderate R&D needed on module interconnection/mechanics/FE chip (FSSR2) –CMOS MAPS option new & challenging technology: can provide the required thickness existing devices are too slow Extensive R&D ongoing on 3-well devices 50x50um 2 –Hybrid Pixel Option: tends to be too thick. An example: Alice hybrid pixel module ~ 1% X 0 Possible material reduction with the latest technology improvements Viable option, although marginal PRESHAPERDISCLATCH

20 30 marzo 2009F.Forti SuperB Status CSN120 Attivita’ finalizzate alla stesura del TDR a fine 2010 R&D sulle 3 opzioni per Layer 0: –CMOS MAPS per dimostrazione fattibilita’ di modulo a pixel multichip con specifiche SuperB (tutte le sezioni coinvolte) –Pixel ibridi: riduzione del pitch e del materiale supporto/cooling per target Layer0-SuperB (tutte le sezioni coinvolte) –Continuazione attivita’ Striplets/FSSR2 (TS) (backup solution for Layer0) Layer esterni: –Design componenti moduli (sensori+fanout, valutazione chip lettura e “ibrido intelligente” (TS+PV chip). –Meccanica Layer esterni (TO) –Interesse di gruppi non italiani al design dei layer esterni Meccanica: –Design beam-pipe (PI), –Light support and cooling for Layer0 modules (PI,MI, TO), –Module design for the external Layers (TO), –Design the full SVT support structure (want to have the Layer0 easily accessible for replacement). Important interplay with IR design (SLAC-PI-TO) Off Detector electronics (MI) and DAQ Development (BO) Simulazione: background, fast simulation per ottimizzare layout SVT. Attivita’ 2009 per SVT - P-SuperB Sezioni: Bologna, Milano, Pavia, Pisa, Roma III, Torino, Trieste

21 30 marzo 2009F.Forti SuperB Status CSN121 ½ MIP SVT (SLIM5) Beam Test Sep.’08 @ CERN Successfully tested two options for Layer0: CMOS MAPS matrix with fast readout architecture (4096 pixels, 50x50  m pitch, in-pixel sparsification and timestamp) –Hit efficiency up to 92% (room for improvement with sensor design optimized) –Good uniformity across the matrix. –Intrisinc resolution ~ 14  m compatible with 50  m pitch and digital readout. Thin (200  m) striplets module with FSSR2 readout chips (not optimized to read the n-side) –S/N=25 (p-side), Efficiency > 98% First demostration of LVL1 capability with silicon tracker information sent to Associative Memories MAPS Hit Efficiency vs threshold MAPS resolution vs threshold

22 30 marzo 2009F.Forti SuperB Status CSN122 Low mass support & cooling for Layer0 pixel modules TFD Lab ready in Pisa since Oct. 2008 Developed a module support structures with cooling microchannel integrated in the Carbon Fiber/Ceramics support. 0.35 % X 0 –The total thickness of the support structure + cooling fluid + peek + glue is: 0.35 % X 0 –Consistent with the requirements First thermoidraulic measurements in good agreement with simulation and within specs. Cooling system based on microchannels can be a viable solution to the thermal and structural problems of the Layer0 detector, Simulated module Carbon Fiber Module T FLUID 9.5 °C Heater Pw2 W/cm 2 Capacity0.7 Kg/min T _IN 41.1 °C T _OUT 43 °C P _IN 2.6 bar 12.8 mm 3 mm Simulation: T_IN = 37 °C (variation of several degrees possible due to uncertainty on thermal conductivity of kapton and glue) Details of Ceramic and Carbon Fiber support Measurements Temp. sensor Heater @ 2 W/cm2 12.8 mm 1.1 mm

23 30 marzo 2009F.Forti SuperB Status CSN123 Set-up Lab TFD Test Station Test-bench set-up DAQ System Heater Kapton Test-bench set-up Refrigerator Group

24 30 marzo 2009F.Forti SuperB Status CSN124 Ridefinizione strategia R&D su Layer0 Approval of the TDR SuperB Project end of 2008  TDR ready by the end of 2010 MAPS option very promizing …. but now need to accelerate the effort on the technology that has the best chance to fulfill all the requirements to become (by 2010!) the baseline option for Layer0 in the TDR : Hybrid Pixels. Manpower (and chip production schedule!) is compatible with the following schedule of activities: 1.Hybrid Pixels: –Sept 2009 produce small prototype Front-End chip for hybrid pixel (50x50 um pitch, same readout architecture data push developed for MAPS chip, reoptimize analog cell) –Sept 2009 produce pixel sensors (ITC, IRST) –Test with beam Sept 2010 pixel sensor bump bonded to the FE chip. 2.Pixel module integration studies continue (similar characteristics for MAPS/Hybrid pixel modules) to end up with a solid module design for TDR. 3.Continue R&D on MAPS: –Large Matrix (APSEL5D~40 mm2 active area) in production in ~Jan 2010, –Radiation damage studies –Develop Pixel module components –Testbeam on APSEL5D in Sept. 2010, very likely as a single chip (probably no time for MAPS module integration). –Later testbeam (post TDR with MAPS module) At the time of the TDR report on progress on MAPS as possible solution for performance improvements. Design a Layer0 easily accessible for replacement!

25 30 marzo 2009F.Forti SuperB Status CSN125 Spese R&D per Layer 0 - 2009 Piano spese complessivo considerando la nuova strategia dovuta all’accelerazione del progetto: (Pixel ibridi+MAPS) Proposta: Cofinanziamento attivita’ complessiva Layer0 tra fondi CSN1- Regione Lazio: –Attivita’ MAPS + pixel module components gia’ finanziata in CSN1 a Sett. –Fondi Regione Lazio per finanaziamento sulle attivita’ aggiuntive: pixel ibridi, probabile baseline per Layer0 nel TDR ulteriori sviluppi di meccanica per il Layer0 e design beam-pipe, dovute all’accelerazione del progetto. Costi 2009 Layer 0 TDR Assegnati CSN1- 2009 Spese Aggiuntive ItemkE MAPS chip (ST~60 mm2) Jan 2010102 Carriers + Testboard5 Pixel module comp. (Al bus+HDI)20 Meccanica moduli Layer 024 FE chip pixel ibridi (ST-25 mm2)- Sett. 2009 40 Carriers + Testboard 5 Sensori a pixel (ITC-IRST) - Sett. 2009 15 Sviluppi meccanica Layer 0+Beam Pipe 41 TOTALE151101 Fondi Regione Lazio Chiediamo di poter utilizzare gia’ da ora parte dei finanziamenti gia’ assegnati (chip MAPS) sulle nuove attivita’ per 2 motivi: Tempi ancora incerti su disponibilita’ di cassa dei fondi Regione Lazio Sottomissione MAPS rimandata a Jan 2010 (ultima sottomissione disponibile Sett 2009 destinata a FE pixel ibridi)

26 30 marzo 2009F.Forti SuperB Status CSN126 Lighter structure, all in Carbon Fiber (CF) –Preliminary studies show that dome-shaped CF end-plates with X0~2% seem achievable (compare 13-26% in BaBar DCH) Design faster&lighter electronics (taking into account detectors options to be possibly installed behind backward end-plates) To control expected increase in occupancy: –studying faster gas mixtures –considering smaller cells –alternative solutions being explored tapered shape of end-plates Build on B A B AR drift chamber concept: no major R&D effort needed, but: The drift chamber LNF Canada: Carleton, McGill, UVic, UBC, TRIUMF

27 30 marzo 2009F.Forti SuperB Status CSN127 Progress in DCH Simulation Fast simulation (V0.0.2) developed for SuperB  Geometry, material, resolutions easily configurable through xml interface goals  compare performances of different DCH configurations  optimize DCH design using additional inputs: machine bkg, spatial resolution for different cell/gas configuration, etc. Example:  compare nominal cell config. with x2 n. of cells, with “realistic” point space resolution Resolution [MeV] gas+wires realistic reso 125  m gas+wires realistic reso 140  m x2 #cells E (B →     ) ‏ 25.4±0.327.4±0.3 E (B  Phi Ks) ‏ 15.6±0.217.6±0.2 Pt [1.0,2.0]10.2±0.211.7±0.2 Pt [2.0,2.5]13.4±0.114.5±0.2 Pt [2.5,3.0]15.8±0.217.5±0.2

28 30 marzo 2009F.Forti SuperB Status CSN128 Setup sperimentale a Frascati Elettronica con discriminatori “on-board” per i 26+26 canali del tracciatore consegnata a inizio 2009. In fase di commissioning. Tracciatore esterno (TOP) Tracciatore esterno (BOTTOM) 6 tubi di test in miscela 80%He 20%iC 4 H 10

29 30 marzo 2009F.Forti SuperB Status CSN129 Prototipo DCH “di riferimento” Un piccolo prototipo di camera a deriva con struttura di cella esagonale à la BABAR in fase di realizzazione @ LNF progetto meccanica terminato  ordinati i materiali per la meccanica, attesi in settimana progetto elettronica di lettura terminato  basato sulle schede ADS di KLOE  disegno PCB inviato alla ditta L’idea è di iniziare a prendere dati in cosmici con questo prototipo a maggio

30 30 marzo 2009F.Forti SuperB Status CSN130 Particle Identification Hadronic PID system essential for P( ,K)>0.7GeV/c (use dE/dx for p<0.7GeV/c) Baseline is to reuse BaBar DIRC barrel-only design –Excellent performance to 4GeV/c –Robust operation –Elegant mechanical support –Photon detectors outside field region –Radiation hard fused silica radiators –But… PMTs are slow and aging. Need replacement. Large SOB region sensitive to backgrounds so volume reduction is desirable Photon detector replacement –Baseline: Use pixelated fast PMTs with a smaller SOB to improve background performance by x50-100 with identical PID performance

31 30 marzo 2009F.Forti SuperB Status CSN131 Forw/Back PID option Extending PID coverage to the forward and backward regions has been considered Possibly useful, although the physics case needs to be established quantitatively Serious interference with other systems –Material in front of the EMC –Needs space cause displacement of front face of EMC Technologies Aerogel-based focusing RICH –Working device –Requires significant space (>25 cm) Time of flight –Need about 10ps resolution to be competitive with focusing RICH –15-20ps already achieved. Can 10ps be achieved ?

32 30 marzo 2009F.Forti SuperB Status CSN132 PID Institutions

33 33 Attività PID a Padova  Costruzione camere termostatiche  Box in alluminio coibentato, raffreddato con peltier e riscaldato da resistenza; controllato con microcontroller nel range 10 – 40 °C, con precisione 0.1°C. Da migliorare precisione e stabilità a lungo termine (obiettivo: ΔT int ≈10mK con ΔT ext ≈5°C) ‏  Costruzione contenitori per fotorivelatori  Per SiPM (e MPPC): box in alluminio a tenuta di luce, con accoppiamento di precisione per la fibra ottica; contenenti due dispositivi e relativi preamplificatori.  Per MCP: supporti in PVC a tenuta di luce, con accoppiamento per fibra ottica e alloggiamento per amplificatore.  Sviluppo di preamplificatori custom  Amplificatori commerciali toppo costosi: sviluppo un amp. custom basato sul chip THS4303.  Acquisito dispositivi  10 SiPM dalla FBK,  6 MPPC dalla Hamamtsu.  2 MCP dalla Burle  Misure effettuate:  Caratterizzazioni I(V, T)  Misure di dark rate.  Misure di guadagno e linearità vs Vbias e Temp

34 34 Attivita' PID a Padova per il 2009 TOF  Misure su SIPM:  Completamento caratterizzazione  Misura caratteristiche temporali  Misure di efficienza, compresa eff. Quantica  Misura di omogeneità della risposta  Misura delle proprietà di radiation hardness dei SiPM presso fascio di neutroni dei Laboratori di Legnaro (flusso >10^10 per sec e cm^2) ‏  Allestimento setup per misure di risoluzione tempi di volo (radiatori quarzo accoppiati a MCPPMT e SiPM) ‏  Misure risoluzione tempi di volo con cosmici e su test beam al FNAL DIRC  Redsign della Stand Off Box per diminuire la sensibilità del DIRC ai fondi e possibilmente migliorare la risoluzione (sia spaziale che temporale)  Nessuna disponibilità da parte dele istituzioni originariamente coinvolte (LBL, Saclay)  Padova, avendo la disponibilità di un ingegnere meccanico, ha offerto aiuto nella progettazione della nuova Stand Off Box e del relativo supporto per il TDR  Attività già iniziata da parte dell’Ing. Benettoni

35 30 marzo 2009F.Forti SuperB Status CSN135 The electromagnetic calorimeter *Barrel *BaBar barrel crystals not suffering signs of radiation damage. They’re sufficiently fast and radiation hard for SuperB needs  They can be reused. (Would have been) most expensive detector component *Background dominated by radiative Bhabhas. IR shielding design is crucial *Endcaps *Best possible hermiticity important for key physics measurements *New forward endcap *backward endcap is an option BaBar Barrel 5760 CsI(Tl) Crystals Essential detector to measure energy and direction of g and e, discriminate between e and p, and detect neutral hadrons

36 30 marzo 2009F.Forti SuperB Status CSN136 Forward and backward EMC *Forward endcap –BaBar CsI(Tl) endcap inadequate for higher rates and radiation dose of SuperB Need finer granularity Faster crystals and readout electronics comparable total X0 –Option 1: LYSO crystals frees 10cm for a forw. PID system radiation hard, fast, small Moliere radius, good light yield expensive (~40$/cc) at the moment –Option 2: retain 3 outer rings of CsI(Tl), LYSO the others less expensive no space for forw. PID system *Backward endcap (option) –Pb plates and scintillating tiles with fiber readout to SiPMs

37 30 marzo 2009F.Forti SuperB Status CSN137 Institutions involved in the EMC project BergenBackward EMC CaltechForward EMC (calibration, DG optimization, DAQ, crystals) PerugiaForward EMC (mechanics, electronics, simulation analysis) Roma1Electronics Barrel + forward Queen Mary, London

38 30 marzo 2009F.Forti SuperB Status CSN138 February 15-18 2009, Orsay Paris Claudia Cecchi University of Perugia and INFN

39 30 marzo 2009F.Forti SuperB Status CSN139 February 15-18 2009, Orsay Paris Claudia Cecchi University of Perugia and INFN

40 30 marzo 2009F.Forti SuperB Status CSN140 February 15-18 2009, Orsay Paris Claudia Cecchi University of Perugia and INFN

41 30 marzo 2009F.Forti SuperB Status CSN141 11/03/2009 Claudia Cecchi

42 30 marzo 2009F.Forti SuperB Status CSN142 11/03/2009 Claudia Cecchi EMC Summary Mechanics –Space between modules. Various options under examination: – Whole structure insteanot modular design? Not recommended by engineer ( problems of integration, handling, recovery) –Maintain the Babar structure, putting inside a single hole 4 LSO crystals (dimensions of BaBar crystals are half of superB design) ? –Geometry with LSO crystals the same size of BaBar ones? –All under investigation Electronics –Rome1 has started to study all the possible solutions for the readout and the electronics. –Possibility to use CMS electronics, but dynamic range too small (LYSO has more light) Simulation –Simulation of the EMC is well established and running. –Different geometry have been investigated and others will be studied –Missing: single particle shoot + background in the full simulation to study the occupancy

43 30 marzo 2009F.Forti SuperB Status CSN143 TEST BEAM 11/03/2009 Claudia Cecchi 2 LSO crystals (already tested in the lab) will be tested at BTF first week of April (PMT, APD) and in June. TB with 25 crystals: - BTF end of 2009 50 -750 MeV + tagged photons - CERN first half of 2010 up to 3.5 GeV Procurement of crystals: 8 pcs ordered in St. Gobain in 2008 (4.9 Keuro/pc T.V.A. not included) will be produced as soon as we give them final dimensions (in discussion with D.H.), 17 crystals missing, part from INFN part from USA. Mechanical structure: 32Keuro assigned to Perugia in 2009 Electronics: will use CMS, plus what has to be redone/adjusted according to our needs (under study) COFINANZIAMENTO REGIONE LAZIO

44 30 marzo 2009F.Forti SuperB Status CSN144 Provides discrimination between  and  ±. Help detection and direction measurement of K L (together with EMC) Composed by 1 hexagonal barrel + 2 endcaps as in BaBar Add absorber w.r.t. BaBar to improve  /  separation. Amount and distribution to be optimized –7-8 absorber layers –reuse of BaBar IFR iron under evaluation Use extruded scintillator a la MINOS coupled to geiger mode APDs through WLS fibers –expected hit rates of O(100) Hz/cm 2 d –single layer or double coord. layout depending on the x-y resolution needs The Instrumented Flux Return

45 30 marzo 2009F.Forti SuperB Status CSN145 News since Sept. 2008 Waiting for simulation of the neutron flux, we have to design a detector not affected by the problem of SiPM/MPPC aging due to neutron irradiation: in the worst case scenario we have to bring all the photodetectors out of the detector –4m of WLS + 10m of clear fibers –Reduction of factor ~3 in number of p.e. to be recovered, keeping the same time resolution Increasing the number of WLS fibers, from 1 to 4, on 2x2 mm 2 SiPM Increasing the fiber’s diameter from 1.0 to 1.2 mm Playing with fibers position and/or scintillator coating to maximize the light collection As 2-nd option we are considering also the “double coord layout”: orthogonal scintillator bars, 1cm thick (mechanically rather complicated)As 2-nd option we are considering also the “double coord layout”: orthogonal scintillator bars, 1cm thick (mechanically rather complicated) 1 st option 2 nd option

46 30 marzo 2009F.Forti SuperB Status CSN146 IFR status: ongoing activities Detector R&D: –efficiency and time resolution studies with more (Φ=1mm for the moment) fibers per scintillator, with 2x2 mm 2 SiPM –Optimization of mechanical coupling: WLS/clear fibers and fiber/photodetectors FE electronics: –Optimization of FE amplifiers: gain x bandwidth and noise studies Detector and background simulation –absorber optimization –reuse of BaBar flux return Detector Design/Mechanics –Study of the detector layout –Study of the Prototype layout superB IFR simulation

47 30 marzo 2009F.Forti SuperB Status CSN147 Cosmic ray test setup Cosmic test setup MPPC module 47

48 30 marzo 2009F.Forti SuperB Status CSN148 Latest results about time distribution of the 1.5 phe corresponding to 2.5 hit (Tbest): 1.2 nsec resolution 48

49 30 marzo 2009F.Forti SuperB Status CSN149 Plans for the TDR Construction and test of a prototype to measure/confirm performances Final layout of the single detector module: scintill + WLS fiber + photodetector based on R&D and prototype test results –Number of fibers per scint. bar –Kuraray / Saint-Gobain and diameter –Type of photodetectors : SiPM or MPPC, active surface dimensions Mechanics –understand if we will reuse the Babar flux return or we need to build a new one –module layout and assembling Development and test of the Front End Electronics: –amplifier –discriminators –TDC Responsabilità IFR R&D rivelatore (Ferrara) Meccanica (Padova, Ferrara) Elettronica (Ferrara) Prototipo e beam test (Ferrara, Padova) Full simulation (Ferrara) Fast simulation (Padova) Ottimizzazione rivelatore + fondi (Ferrara, Padova) OHIO State University

50 30 marzo 2009F.Forti SuperB Status CSN150 Test SiPM con neutroni @ ENEA/Frascati Il generatore di neutroni da 14 MeV FNG (Frascati Neutron Generator) si basa sulla reazione di fusione T(d,n) α e produce fino a 10 11 n/s in modo continuo o impulsato. FNG produce anche neutroni da 2.5 MeV (fino a 10 8 n/s) utilizzando bersagli deuterati mediante la reazione di fusione D(d,n) 3 He. Test con 14 MeV (~ decine di minuti ) e con 2.5 MeV (qualche giorno) Costo facility ~1000 Euro/giorno Il gruppo di Roma1 (in transizione su EMC) si occuperà di questi test. 50

51 30 marzo 2009F.Forti SuperB Status CSN151 Nuova strategia per prototipo IFR 1)Necessità di poter operare anche in un ambiente ‘ostile’ come flusso di neutroni 2)Utilizzo di fibre chiare per allontanarsi dalla zona ‘calda’ 3)Aumento numero di fibre scintillanti per recuperare la luce persa 4)Aumento dimensione del fotorivelatore per leggere tutte le fibre di una slab di scintillatore COSTI: Cofinanziamento costo complessivo prototipo con fondi della Regione Lazio A settembre 2008 richiesti 93 KE, finanziati 77 KE (differenza 16 KE) Le necessità aggiuntive saranno quantificate meglio alla fine di questa fase di R&D, attualmente la migliore stima è 7 KE di fibre WLS 32 KE di fibre chiare 14 KE di differenza di costo del fotorivelatore da (1x1)mm 2 a (3x3)mm 2 Cofinanziamento totale richiesto sui fondi della regione Lazio circa 70 KE 51

52 30 marzo 2009F.Forti SuperB Status CSN152 Electronics and DAQ organization Two domains: –Electronics, Trigger and DAQ Fast Control and Timing System Data Links FEB mezzanines Hardware Trigger (L1) ROM Boards –DAQ/Online. HLT cluster –Event Builder Configuration and monitoring software

53 30 marzo 2009F.Forti SuperB Status CSN153 Electronics, Trigger, DAQ Working conditions –Trigger rate is expected to be of the order of 100 kHz at 1036. The sole Bhabha’s background: 50 kHz ? – baseline target rate of about 150 kHz. Issue of safety margin. How much, and where do we put the safety ? –A readout window (1us) has to be foreseen –Synchronous mode preferred. Clock O(56MHz). Clock and Fast Control System –Clock distribution not at all trivial to ensure phase synchronization –Try to use commercial component as much as possible (FPGA) Relying on SLHC development (such as GBT) very risky Try to define strategic placement of components so that radiation damage is kept under control. –Different options to be studied and simulated L1 Trigger – Primitives @ 7MHz Dataflow – Local buffers, overlapping readout windows Frontend model – synchronous, fixed latency Radiation mitigation High Level Trigger and pre-processing boards – input bw O(15MB/s)

54 30 marzo 2009F.Forti SuperB Status CSN154 ETD FCTS FEB Hardware Trigger L1 Clock Commands L1 accept L1 primitives L1 accept Clock Commands ROM Event fragments Throttle mechanism: FCTS command to L1 Clock Commands MEP Destination Address Throttle Request Detector HLT Throttle Request

55 30 marzo 2009F.Forti SuperB Status CSN155 ETD main features Synchronous and fully triggered system. –Triggered transfer of the event fragments from the FE boards to the ROM, through optical data links. –Asynchronous event fragments transfer to the HLT. Transfer of Multi Event Packets form ROMs to the HLT in pull mode: to the idle worker node of the HLT cluster asking for data. Standard for the whole collaboration on custom electronics: –FEB mezzanines –ROM boards –Data Links –FCTS distribution system and receivers (see FEBs).

56 30 marzo 2009F.Forti SuperB Status CSN156 Interests FCTS –LAL, Napoli, Padova Data Links –Bologna, LAL, Napoli, Padova FEB Mezzanine –LAL Hardware Trigger – ? ROM –Bologna, LAL, Roma Tor Vergata

57 30 marzo 2009F.Forti SuperB Status CSN157 R&D Issues, priorities, plans have to be better understood and agreed. –FCTS and Data Link Architecture, components and validation for radiation. –ROM as general purpose standard board On custom electronics On commodity hardware –Is it that feasible? –Does it allow us to save money? Hardware Trigger not covered yet. –BaBar solution with reduced latency is the baseline. Bhabha veto is needed and feasible? Does the vertex detector trigger really help? How do they affect the combined trigger architecture? Design of the architecture and of fundamental building blocks of the system launched.

58 Incontro con referees - 18 marzo 2009 58 Computing principale impegno: fornire gli strumenti e il supporto per la stesura del TDR del rivelatore (e della macchina) ‏ –Fast simulation –Full simulation –Tools collaborativi –Tools per lo sviluppo del codice attività più a lungo termine: preparazione del "computing TDR" –SuperB Computing planning group

59 Incontro con referees - 18 marzo 2009 59 Attività avviate recentemente –GRID, produzione distribuita creata la VO SuperB, utilizzo della GRID goal primario utilizzo risorse CNAF: graduale apertura ai collaboratori SuperB, già oggi si può utilizzare per produzione simulazioni Geant4 –interazione fast/full simulation (v. bkg) ‏ –consolidamento aspetti operativi organizzazione dei tools per la produzione e il quality control –infrastruttura offine –tools amministrativi

60 Incontro con referees - 18 marzo 2009 60 Necessità di personale –il gruppo Computing deve fornire alla collaborazione un supporto che sta diventando sempre più ampio e impegnativo normalmente buona parte di tale supporto è fornito dal laboratorio ospitante, questo non succede nel nostro caso –c'è necessità di poter contare su un alcuni tecnologi/fisici con background tecnico da impiegare a tempo pieno su SuperB –individuate 5 aree "urgenti" Software development support Collaborative and administration tools support Offline infrastructure support Simulation Support Data bookkeeping, distributed computing

61 30 marzo 2009F.Forti SuperB Status CSN161 Detector simulation Fast simulation –Parametrized, for evaluating physics impact of detector choices Full simulation –GEANT4 full description, for background effect evaluation

62 Incontro con referees - 18 marzo 2009 62

63 full sim is delivering too

64 Risorse PRELIMINARY

65 30 marzo 2009F.Forti SuperB Status CSN165 Items per R&D da cofinanziare con Regione Lazio per TDR SVT –Cofinanziamento prototipo modulo Layer 0 Finanziato da INFN per 150K Uso di circa 40K dai fondi PRIN Da cofinanziare per 100K – vedi dettaglio temporale EMC –Cofinanziamento del prototipo di calorimetro 8 cristalli INFN (gia’ acquistati) (circa 50K) Struttura meccanica INFN 32K 8-9 cristalli DOE (circa 55K) 8 cristalli cofinanziati (circa 55K) – vedi dettaglio temporale IFR –Cofinanziamente del prototipo IFR Già finanziato dall’INFN per 77K Da cofinanziare il rimanente, circa 70K Elettronica –Acquisto strumentazione di test (60+100K), ancora da definire

66 30 marzo 2009F.Forti SuperB Status CSN166 Postdoc e contratti tecnici da finanziare sui fondi della regione Lazio Contratti SVT 1 ingegnere meccanico Pisa 1 ingegnere elettronico Pavia 1 assegno x DAQ a Bologna 1 assegno x simulation and background a Milano(sharing computing) Contratti DCH 1 Fisico per simulazione dei processi fisici rilevanti e dei fondi macchina per la ottimizzazione delle prestazioni della DCH 1 Ingegnere Elettronico per il progetto dell’elettronica della DCH Contratti EMC 1 assegno per Perugia Contratti IFR 1 assegno per sviluppo full simulation Ferrara 1 assegno per R&D del rivelatore Ferrara 1 assegno per ottimizzazione rivelatore e studi di fondi Padova 1 assegno per realizzazione prototipo e test beam Ferrara Contratti Elettronica 1 assegno 1 ingegnere

67 30 marzo 2009F.Forti SuperB Status CSN167 Contratti per computing

68 30 marzo 2009F.Forti SuperB Status CSN168 Resources Preliminary

69 30 marzo 2009F.Forti SuperB Status CSN169 Ultime nuove Situazione giapponese –Il progetto di SuperKEKB ad alta corrente è stato bocciato Troppo costoso e poco performante –I giapponesi hanno iniziato a studiare l’opzione SuperBeam (italian option) –Tempistica non chiara per avere un progetto consistente (> 6 mesi) Problemi a Tor Vergata –Il nuovo rettore non è entusiasta di SPARX e SuperB. –Negoziazione iniziata per avere chiare garanzie che se la costruzione inizia non ci saranno intoppi –Si esplora la possibilità di realizzare SuperB sotto LNF + ENEA

70 30 marzo 2009F.Forti SuperB Status CSN170 Verbale F.Forti presenta gli update sulle attività di SuperB da Settembre 2008. I test di macchina previsti su DaFne del concetto di crab-waist si sono conclusi in modo soddisfacente, e sostanzialmente si possono considerare concluse le verifiche sulla fattibilità dell’acceleratore. Nel corso del 2008 il progetto SuperB ha ricevuto l’approvazione del comitato di review internazionale (Dainton committee), del Mini MAC(Dorfan committee) e di ECFA. A dicembre 2008 il direttivo INFN ha approvato il progetto speciale SuperB TDR, per la preparazione del Technical Design Report, ed è in corso di finalizzazione un accordo con la regione Lazio per il finanziamento delle attività TDR di SuperB, previsto essere 5M€/anno per tre anni. Tale finanziamento potrà co-finanziare, fra le altre cose, attività di R&D sul rivelatore e contratti finalizzati alle attività per il TDR. Il progetto SuperB si è dotato di una struttura organizzativa, che comprende un gruppo di management (Direttore e tre deputies) e quattro strutture principali: Acceleratore, Rivelatore, Computing, Sito e infrastrutture. Si prevedono due fasi per la preparazione dei prossimi report: –a fine 2009 i documenti per l’approvazione da parte del governo: una Technical Description dell’acceleratore, un Accelerator site study, un design report sul rivelatore; –a fine 2010 i documenti necessari per una review tecnica completa e il baselining di costi e schedule: Technical Design Report/Engineering Design Report per acceleratore, sito, rivelatore. Il TDR del computing potrebbe arrivare successivamente. Forti procede a presentare i dettagli delle attività del gruppo SuperB per la preparazione del Technical Design Report, disponibili nella presentazione. Vengono individuati gli elementi per cui si può ottenere il cofinanziamento della regione Lazio, al momento in cui i finanziamenti diventeranno disponibili. Tali elementi sono: SVT: Cofinanziamento prototipo modulo Layer 0 EMC: Cofinanziamento del prototipo di calorimetro IFR: Cofinanziamente del prototipo IFR Elettronica: Acquisto strumentazione di test L’entità dei finanziamenti è ancora da definire. Le richieste finanziare consistono nello sblocco dei SJ sul materiale inventariabile, alcune integrazioni di consumo, e l’integrazione delle missioni per poter svolgere le attività previste durante il 2009

71 BACKUP

72 30 marzo 2009F.Forti SuperB Status CSN172 Two colliding beams –radiative Bhabha  dominant effect on lifetime –e+e- e+e- production  ~3% contribution to lifetime, important source for SVT layer-0 Single beam –synchrotron radiation  strictly connected to IR design –Touschek  negligible in BaBar, important in SuperB –beam-gas –intra-beam scattering Machine backgrounds

73 30 marzo 2009F.Forti SuperB Status CSN173 Radius, thickness, resolution Technological solutions depend critically on L 0 radius, thickness, resolution Fast simulation studies for various decays have been performed A full, more detailed reassessment is needed for the TDR. 10  m resolution5  m resolution BaBar MAPS MAPS low mass solution would leave more flexibility for radius (ie background) and resolution Hybrid pixels will force to use the smallest radius and/or better resolution Striplets (same MAPS material) require larger radius, performance marginal  t resolution in B  decays vs L0 X0(%) beam pipe material: 0.4% X0 b. p. inner R 1cm, o.r. 1.1 cm layer0 radii = 1.2, 1.5, 1.7 cm material for L0 = [0.2-1.5] % X0 hit resolution = [5-15]  m

74 30 marzo 2009F.Forti SuperB Status CSN174 Plan proposed in CSN1 in Sept. 2008: build a multichip CMOS MAPS prototype module with specs close to the SuperB Layer0 requirements. Activity started  document with specs for MAPS module components. All the module components the same for Layer0 module based on Hybrid Pixels. SVT Activities for TDR – Layer 0

75 30 marzo 2009F.Forti SuperB Status CSN175 SVT Activities for TDR – Layer 0 Use modified EDRO board (SLIM5) with large FPGA, memory and optical links (i.e. flexible) as interface between FE chips and SuperB trigger and DAQ. Layer 0 module rates: 20 Gbit/s full rate (FE data push), 3 Gbit/s triggered rate Pixel module components Pixel BUS needs: low material, many lines, high frequency (> 100 MHz), –contact started with CERN PCB shop (produce and test Al prototypes) Different options under study on Interfaces (HDI- power/signal input and data output link) & SVT data transmission

76 30 marzo 2009F.Forti SuperB Status CSN176 CDR Cost Estimate A full cost estimate of the SuperB project has been done –Based on Babar/PEP-II actual costs –Escalated from 1995 to 2007 –Bottom-up for almost all elements Separate new components from reused elements –Replacement value of reused components = how much would it cost today to rebuild those components (extrapolated from Babar/PEP-II costs) –New costs: everything that’s needed today, including refurbishing –Transport is not included, but disassembly and reassembly is. Keep separate categories: –EDIA: engineering, design, inspection and administration (man-months) –Labour: technicians (man-months) –Materials and Services: 2007 Euros.

77 30 marzo 2009F.Forti SuperB Status CSN177 Milestones

78 30 marzo 2009F.Forti SuperB Status CSN178 SuperB Footprint SuperB rings