Download presentation
Presentation is loading. Please wait.
1
Worldwide testbeam session summary Felix Sefkow DESY ECFA workshop Durham September 4, 2004
2
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 2 Session goals Had half day session at LCWS in Paris on TB needs and facilities Situation documented in “Worldwide LC testbeam” report –http://www.linearcollider.ca:8080/lc/vic04/abstracts/detector/ testbeam/wwlctb_working_group.doc Here: get an updated overview of planned testbeam efforts Launch activity to submit internationally coordinated proposal for testbeams for LC detector R&D Prepare statement for ICFA to alarm lab directors of our concern that testbeam supply will not need our demands
3
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 3 Outline Summary of summaries: Demand Supply Initiatives
4
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 4 Testbeams for calorimeter R&D
5
5 Geant4 hadronic shower models. GEANT4 has extensive set of hadronic shower models, from which we would like to select. GEANT4 has extensive set of hadronic shower models, from which we would like to select. Several experiments have compared testbeam data with Geant4 predictions. Several experiments have compared testbeam data with Geant4 predictions. However, used to characterize existing designs, not to design new detectors. However, used to characterize existing designs, not to design new detectors. “Particle Flow”, or imaging calorimeter, places much more stringent requirements on simulation. “Particle Flow”, or imaging calorimeter, places much more stringent requirements on simulation. Cottage industry to run all available sets to demonstrate dispersion. Cottage industry to run all available sets to demonstrate dispersion. See talks in simulation session. See talks in simulation session. Norman Graf, SLAC
6
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 6 Hadronic shower model dependence Remember: need to optimize imaging capability of HCAL Study by G.Mavromanolakis
7
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 7 Calorimeter testbeam needs 10 8 – 10 9 events = (10 – 100) days / duty_factor (@ 100 Hz DAQ rate)
8
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 8 CALICE testbeam plans
9
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 9 LCcal beam needs Left over: more hadron data scan different gains in pad electronics combined test with Hcal Calorimeter re-arrangment (including W absorber) Beam time: at least one week e/h beam 10-70 GeV Problem: time and manpower Possible solution: join efforts with other groups SUMMARY after 2003 runs Paolo Checchia, Padova
10
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summary 10 ECal R&D in N. America -- Test Beam Readiness/Plans Silicon-tungsten SLAC, Oregon, Brookhaven (SOB) Scintillator tiles – tungsten U. Colorado, Fermilab Hybrid silicon/scintillator – tungsten U. Kansas Ray Frey, Oregon
11
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summary 11 Si/W Status and Plans Note that current design is optimized for warm, but could be optimized for cold Would require digital pipeline → this is current focus Would timing still be desirable? This year Qualify prototype detectors already in hand Fabricate initial RO chip for technical prototype studies Readout limited fraction of a wafer ($) (64 of 1024 chns.) Chips probably not in hand before Jan 2005 2005 Electronics evaluations Bump bonding “Technical” test beam, summer 2005 at earliest A few layers with 1 st round detectors and chips Plan for a full ECal module (similar to eventual ECal) Finalize thermal plans, mechanics Provide correct front radiator for hadron shower validation in test beam. Earliest beam test: Summer 2006 Continue to evaluate configuration options Layering, segmentation What people often neglect… Ray Frey
12
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summary 12 Tile ECal (contd.) (from Uriel Nauenberg) Will be ready for test beam in 2006 if funding becomes available in 2005 to build a module. The big issue is electronics; we have very little help with that. The module will consist of 60 layers or 45 layers For 11%/root(E) resolution we need 60 layers of 1/2 X0 Tungsten and 2 mm of scintillator, not 45. For 13%/root(E) then we can go with 45 layers of 3/4 Xo and 3 mm scintillator; (Investigating the spatial resol. deterioration.) Usual disclaimer
13
13 ECAL R&D; Tungsten ECAL with both Si and Scintillator sampling Concept: physics requires high granularity, reasonable sampling frequency, large BR 2, compact R M. => ECAL probably should be W absorber, some Si, some cheaper sampling medium (Scint.). All Si is probably best IF it can be cost-effective, IF timing is not important (less so now!), and IF really large R is not dictated by the physics. All Scintillator is probably prohibitively expensive due to channel count at sufficient granularity Ongoing R&D: mostly simulation based on different design possibilities –EM energy and angular response studied –Photon/hadron separation in progress –Critical items Does coarse scintilllator granularity work for a hybrid ? Gap size (compactness) Test-beam Wishes & Goals: –could validate the EM response of hybrid ECALs with mixed sampling media Eg. Anti-correlation predicted in Si and Scint. response –In collaboration with existing groups encourage that data taking opportunities with large volume HCALs and expensive Si-W ECALS can also be used to explore alternative ECAL designs to Si-W Ideally gaps eg. alveoli in the CALICE ECAL could be used to study alternative sampling layers. A hanging-file type approach would facilitate understanding the intrinsic response (but not an engineered hermetic solution …) –Have funds available which can contribute significantly to a prototype ECAL construction and testing on a 2-year time- scale. Envisage wanting electron, pion beams in summer 2006 Concurrent running with HCAL activities –Exactly how to proceed depends on developing collaborations and results of simulation studies (want to use test-beam time and construction funds wisely) Graham W. Wilson for Kansas, Kansas State Universities Ray Frey
14
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 14 Asian plans Updates since Paris: –Still expect KEK PS runs in 2005 –J-PARC from 2008 onwards –KEK linac 2006 onwards Pb Sci TB finished, now new Huge detector design New W Sci ECAL with SiPMs Testbeam 2006 onwards Participate with Tsukuba drift chambers in CALICE TB at DESY
15
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 15 Muon and Tail Catcher (V.Zutshi, NIU) Vigorous R&D for a muon detector which could also serve as a tail-catcher underway in gas and scintillator technologies. All proponents are working towards exposing their prototypes to a test beam in the 2005-2006 period. Expecting increased coordination between groups as the test beam becomes a reality.
16
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 16 Tracking / Vertexing (B.Schumm, Santa Cruz) A: TPCs need B > 0, but 1 - 2 Tesla sufficient for most studies International tracking group anticipates testbeam needs beginning in late 2004 Very rough guesstimate is 75-100 weeks of facilities time between now and beginning of 2006 Need for high-field magnet on test-beam line is an open question. UCSC has addressed this for Si; what about others techonolgies? Most-requested beam is few GeV hadrons or muons
17
M. Woods, SLAC ECFA ILC Study, Sept. 200417 Outlook on IPBI IP Beam Instrumentation is a critical aspect of the Machine-Detector Interface. IPBI should be considered as one of the Detector subsystems – measurements of luminosity, energy, polarization (and electron ID at small polar angles for 2-photon veto) are critical for the ILC physics program. IPBI R&D Efforts are well underway in all 3 regions. There is an identified and growing need to develop prototypes, which need access to test beam facilities. At SLAC, a Letter-of-Intent for LC Beam Instrumentation Tests in ESA was submitted to SLAC in Fall 2003 and presented to the SLAC EPAC. Response from the EPAC and the SLAC Director was very positive. First 3 Test Beam Requests have been submitted to SLAC and cost estimates have been made. Requesting a run in June 2005. Currently waiting for SLAC response as we go thru evaluation of SLAC’s efforts for ILC (I expect a positive response)
18
M. Woods, SLAC ECFA ILC Study, Sept. 200418 First IPBI Beam Tests Proposed to SLAC 1.Energy BPMs (T-474 submitted) U. of Notre Dame, UC Berkeley, UC London, U. of Cambridge, SLAC - Mechanical and electrical stability at 100-nm level - BPM triplet at z = 0, 2.5 and 5.0 meter spacing. BPMs 1 and 3 define straight line. Monitor BPM2 offset over time scales of minutes, hours - 2 adjacent BPMs to test electrical stability, separate from mechanical 2.Synchrotron stripe diagnostics (T-475 submitted) U. of Oregon, SLAC - test chicane scheme with wiggler magnet - characterize detector (quartz fiber / other) performance and capabilities 3.Pair detectors (T-476 submitted) Molecular Biology Consortium, U. of Hawaii, Tohoku U., Brunel U., CERN - use “spray” beam of ~ 4-GeV electrons to mimic pair background - test speed (at nano-second level) of both 3-d and planar Si - characterize detector response to “pair background”; can vary spray beam energy and absorber thickness in front of detector plane - use MonteCarlo to superimpose 250 GeV electron to determine electron id efficiency
19
M. Woods, SLAC ECFA ILC Study, Sept. 200419 Other IPBI Beam Tests Possible in ESA 1. IP BPMs (necessary for fast inter-train and intra-train feedbacks) - Sensitivity to backgrounds, rf pickup - Mimic LC geometry, including fast signal processing (but no feedback) - Sample drive signal to kickers 2. Tests with short bunches (~100-300 m possible) - EMI for beam instrumentation or Detector electronics - collimator wakefield tests 3. Single Particles (electrons, photons, pions) - 2-25 GeV particles with 1 or less particles/bunch at 10Hz for LC Detector test beams 4. Fixed target to mimic beamsstrahlung and disrupted beam - for synchrotron stripe energy spectrometer - for IP BPM tests 5.IR Mockup - Mimick beamline geometry at IP within +-5 meters in z and Prospects less clear for these five
20
A summary of world-wide test beam facilities Erik J. Ramberg FNAL 4 Sept. 2004
21
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summary 21 A list of available facilities with multi-GeV beam FNAL - p: 8-120 GeV: available 2004-on SLAC - e, 1-30 GeV: available 2004-on DESY – e: 1-7 GeV: available 2004-6 CERN – e, p: (PS) 1-15 GeV: (SPS) 10-200 GeV: likely available 2006-on IHEP (Protvino, Russia) – e, p: 1-45 GeV: available See “Report on WorldWide Linear Collider Test Beam Effort”: http://www-hep.uta.edu/hep_notes/lc/lc_0005.pdf
22
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summary 22 General Impressions of Test Beam Facilities DESY: Probably the best place for low energy (< 6 GeV) electrons IHEP: Can get to higher energies for electrons. Good general purpose beam. Limited availability during year. CERN: excellent all around beams. Limited availability during year. Unknown future. SLAC: Excellent for accelerator component testing. Secondary beams for detector testing are good but have low rate. FNAL: Good availability with general purpose beam. Probably have to share with other users. Electrons are problematic. 2x 1 month Could be improved, would need investments
23
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summaryTB Strategy J. Yu 23 Competition on facilities from other then LC community is significant Funding situation in the regions are not all ideal –European and Asian communities seems to have better support for detector R&D and TB than North American Need to coordinate within the LC community to meet all the TB needs in a most optimal manner We are in this together so we need to work together as one entity Jae Yu:
24
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summaryTB Strategy J. Yu 24 Strategy and Time scale For calorimeter there are two facilities that could meet most the needs –FNAL – MTBF –IHEP, Protvino FNAL directorate willing to work with our community Have our primary contact person at Fermilab (E. Ramberg) Let’s shoot for FNAL first –FNAL Fall PAC meeting: Nov. 12 – 14, 2004 “first” means: will soon be happy to make use of all suitable resources
25
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summaryTB Strategy J. Yu 25 Strategy and Time scale, cnt’d Write a world-wide TB proposal ( or MOU if you like) to Fermilab directorate –Starting with Calorimeters in all regions –Including other detectors that would be ready – We could build this upon existing efforts and expand to integrate activities world-wide A workshop for this proposal planned: Sept. 23 and 24 at ANL –A focused group of people from all regions to write the proposal Submit the proposal to Fermiab directorate by Oct. 10 for a possibility of PAC review and endorsement –Request help to our leadership for this Turn this into a U.S. NSF MRI proposal for North American TB equipment support
26
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summaryTB Strategy J. Yu 26 TB One Page Executive Summary Introduction for TB needs –LC Physics as detector challenge –Novel technologies and approach to meet this –Technology decision giving momentum and setting time-scale –Detector concept studies and eventual TDR require serious TB efforts NOW –Many detector R&D are mature for test beam Primary goals for TB experiments –Testing of novel technologies and algorithms –Bases for conceptual detector design choices –Simulation verifications and enhancements
27
ECFA LC workshop, Durham, Sept 2004 Felix Sefkow, Worldwide testbeam session summaryTB Strategy J. Yu 27 TB One Page Executive Summary, cnt’d Current and anticipated TB programs –Requirement for facilities Particle species and momentum ranges –CALICE and other calorimeter efforts –Other detector needs –Total coordinated beam time requests Current situation in facilities –Limitations in number of facilities that can meet the needs Existing facilities can meet the need in principle –Availability and scheduling Recommendations and requests –Request the lab directors to recognize the LC TB effort and adjust the priority to meet our needs –Request strong resource support from laboratories –Request endorsement for necessary funding
28
ECFA LC workshop, Durham, Sept 2004Felix Sefkow, Worldwide testbeam session summary 28 Summary Test beam demands are overwhelming, and exceeding availability of facilities Program now entering new phase Level of coordination, too Call for participation in generic LC detector R&D proposal, built on momentum from large calorimeter R&D groups executive summary to ICFA and lab directors today
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.