S.Stapnes1 European Detector R&D and FP7 - Outline Background –New call for IAs (Integrated...
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Transcript of S.Stapnes1 European Detector R&D and FP7 - Outline Background –New call for IAs (Integrated...
S.Stapnes 1
European Detector R&D and FP7 - Outline
Background – New call for IAs (Integrated Activities) in November – it is in fact expected
tomorrow with deadline 29.2.2008. • ESGARD preparing proposal for accelerator R&D (as follow up to CARE) for
this call • IA potentially also very useful for infrastructures related to common R&D –
for detector development for SLHC, Linear Colliders, Neutrinos, etc. – also in this area we need coordination to set our own priorities, to
improve our chances for success, – and also in this area we can benefit from better
coherency/communication among all the actors in the field• EUDET a successful example in FP6 for detector R&D as supported by such
a program
Progress since last meeting Outline of application Next steps
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European Detector R&D and FP7 – WEB- information
WEB page at: http://project-fp7-detectors.web.cern.ch/project-FP7-detectors/Default.htm
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A European Coordination Group for Detector R&D in the FP7 programs:
The successful model for such a group is ESGARD covering accelerator R&D. For detector R&D the activities are much more widely distributed and the major stakeholders are the
main experiments being planned for SLHC, Linear Collider (EUDET), Neutrino and Flavour physics. It is therefore suggested to create a COORDINATION GROUP with representatives for these planned
experiments plus CERN and DESY. The believe is that most of the European detector R&D are focused and organised as part of these collaborations or proto-collaborations.
The detector R&D coordination group must also have effective links to ESGARD to make sure the plans concerning submissions to EU programs in the areas of accelerator R&D and detector R&D are coherent.
The current composition of the group is:– Joachim Mnich, EUDET (Linaer Collider Detectors) – Nigel Hessey and Jordan Nash, upgrade coordinators ATLAS, CMS – Lucie Linssen representing CERN – Rolf Heuer representing DESY – Alain Blondel representing neutrino detectors – Francesco Forti representing flavour factory detectors – One person from ESGARD (or/and frequent communication ESGARD)
The group is lead by Norman McCubbin and Steinar Stapnes.
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National ContactsThe National Contact Group ia a reference group with national representatives. The detector R&D is very
widely distributed activity with many potential project partners, during this process it is important to have discussion partners in each European country that can:
Help to identify the major detector R&D activities in each country Help to identify one (or a few) potential contract partners for EU proposals in the area of detector R&D
(this could typically be national labs taking on coordination roles within one country, or a lead institute) Provide guidance to the Coordination Group during the planning phase (mails and information
concerning the coordination groups work will be distributed to these national contacts).
Names identified by RECFA representatives (and if not received the RECFA representative is used):
Switzerland: Martin Pohl
Germany: Lutz Feld
Slovakia: Miroslav Pikna
Spain: Carlos Lacasta
Portugal: Paula Bordalo
Netherlands: Els Koffeman
Israel: Giora Mikenberg
Czech Republic: Vaclav Vrba
Poland: Filip Zarnecki
Austria: Manfred Krammer
Finland: Kenneth.Osterberg and Eija.Tuominen
Hungary: Gyorgy Bencze Sweden: Richard Brenner
Norway: Steinar Stapnes
Denmark: Peter Hansen
Italy: Massimo Caccia
UK: Norman McCubbin
Belgium: Eduardo Cortina Gil
Bulgaria: Jordan Stamenov
France: Roy Aleksan (need to change)
Greece: Theodoros Alexopoulus
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Call for IAs - summary IA: Integrated Activities ... must combine three elements: networking, trans-national access
(TNA) and joint research activities (JRA).
Used successfully and creatively by EUDET in FP6 to support test-beams and other common infrastructures for the R&D and integration activities, building some of the prototypes (used as part of infrastructures), and to provide travel funds for participants – for ILC detector R&D.
30+ participating institutions and 60+ FTEs … 7 MEURO budget.
Also used by CARE for accelerator R&D of course
The IA call will be on 30 November, deadline 29 February 2008 and then again in 2010. These calls are for both the traditional IA activities and also the new Thematic IAs.
Scope 277 MEURO.
Typical size, 4-6 MEURO with 20 participants, can increase to 10-15 MEURO in special cases with more participants, for 4 years (2009-2012)
Expected to have similar structures to I3s in FP6 (as used by EUDET and CARE)
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AgendasLink to meeting agenda and slides available:
http://indico.cern.ch/categoryDisplay.py?categId=1696
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Proposal strategy Priorities:
1. Common detector R&D facilities needed 2009-2012 (as identified by representatives of the coordination group) Testbeams, Irradiation facilities, Electronics development tools, Software tools -
focus on items/projects which adapt them to next detector R&D stage 2. SLHC detector R&D facilities
Adaptation of the facilities/tools for SLHC detector R&D3. Linear Collider Detector R&D facilities
Focus on facilities that allow follow up of EUDET (combined set up and testing of detectors), plus related electronics, software and detector integration tools
4. Neutrino detector Detector R&D facilities Study of detector elements in testbeams, electronics and software development,
detector integration tools 5. SuperB (mostly covered by above)
Testbeam measurements, irradiations, detectors and software
Many of these facilities/common tools are linked to equipment and projects taking place in the CERN beams but several are also distributed (for example irradiation facilities, electronics, software, etc)
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Outline of proposalThe following key activities are identified. They will in several cases need to be split intoseveral work-packages (will wait for call to be launched to finalise this breakdown). Current ongoing work is to identify main objectives, coordinators, main partners, budget envelopes
Electronics tools for new detectors (example 1) Software developments for detector R&D:
– Geant4 (pileup and also other packages), Fluka (backgrounds), Reconstruction toolkit, Geometry package to allow simulating various layouts efficiently)
Irradiation facilities for detector R&D – crucial in particular for SLHC rates, several such facilities around Europe needed – many improvements needed for SLHC studies (and will obviously also cover needs for anybody else)
Test-beam facilities: – Linear Collider Combined tests (example 2)– SLHC detector testing – Neutrino Detector Testing– Super B Detector Testing
Technical Coordination tools for Linear Collider Experiment(s) Technical Coordination tools for Neutrino Experiment(s)
In addition there will be a Management/Outreach WP
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Outline of proposal - example 1Deep Sub-Micron (DSM) electronics
Main clients SLHC, ILC/CLIC and super-B. Neutrino detectors will profit from the developments, though their need for radiation hardness is less
Proposed activities (being worked out) in table on the right:
Activity presently initiated by Sandro MarchioroContact persons: ILC/CLIC – Christoph de la Taille, Marc
Winter, Leif Jönssen, Luciano Musa SLHC – Philippe Farthouat, Jordan Nash Neutrinos – Alfons Weber, Andre Rubbia B-physic – Valerio Re (Bergamo univ.)
Silicon IC technologies: CMOS 130, 90, 65 nm SiGe on several CMOS
platforms ?? Legacy technologies: .35
micron to ¼ micron Dedicated high voltage
technologies Common MPW activities
for selected processes
Enabling tools: CAE tools, on top of
Europractice class tools Modern system level
simulation tools Libraries and shareable IPs Training and education Test tools:
IC testerWafer prober (300 mmwafers will eventually beunavoidable)
Access to common irradiation facilities
Shareable IP blocks: Optimized and validated
digital libraries Generators for SEU robust
memories Timing generation blocks
(DLLs, PLLs) Analog blocks: Bandgap
reference, AD and DA blocks
Auxiliary technologies: Standard and advanced
bump-bonding 3D interconnect Low cost standard (QFN,
fpBGA, TSOP, etc)
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Outline of proposal - example 2Linear Collider combined testfacilities Beamline adaption Integration facility for parts DAQ combined Tracking infrastructure Calorimeter prototype
infrastrucutre
Related (under the headings softwareand integration tool activities twopages back) Energy flow reconstruction tools Integration tool development
(technical coordination)
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Meeting with
National Contacts
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Similar proposals HadronPhysics in FP6 I3HP has 49 beneficiaries and a 17.4 MEURO EU budget.
– Current project is at http://www.infn.it/eu/i3hp/
– They are preparing a follow-up proposal:http://www.hadronphysics2.eu/. We expect this proposal to request 15 MEURO from the EU.
The EURONS community for nuclear physics.– The present EURONS project has 14.1 MEURO EU funds. EURONS has 9 NA's, 12 TA's and 13
JRA's: http://ec.europa.eu/research/infrastructures/pdf/eurons.pdfhttp://www.gsi.de/informationen/jofu/EURONS/
– They are preparing a new proposal (link not found)
There is the ILIAS (Integrated Large Infrastructures for AstroparticleScience) FP6 project. – Current project got 7.5 MEURO from the EU:
http://wwwilias.cea.fr/scripts/home/publigen/content/templates/show.asp?L=EN&P=293&vTicker=alleza&ITEMID=3
– They are preparing a new proposal under this site: http://www-ilias.cea.fr/scripts/home/publigen/content/templates/show.asp?P=157&L=EN&ITEMID=43
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Budget strategy
Aimed for 15 MEURO - in line with large size of community – And to make sure we can involve them in these important general
facilities that are clearly needed for next phase
Some uneasiness that we enter with two large proposals - accelerators and detectors
What do we do - reducing the detector proposal will drive down the number of participants and funding shares, and hence the attractiveness of proposal both for participants (= some of you) and to the EU. Below a certain limit it makes no sense.
We need to have an agreed common strategy
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Conclusions
Progress is being made outlining an IA – following the plans outlined in our London/Manchester/Berlin meetings – Now have people working on each activity including
contacts to main detector development projects in these areas
– Coordination and National Contact Groups established – Proposal is concentrated on key facilities for Detector
R&D in Europe that we serve a large part of the community and that can be used by several projects
Budget envelope very difficult and impacts the number of groups and projects that can be included
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More slides
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Motivation for coordination ATLAS and CMS have 10-20 active R&D areas each for SLHC upgrade - involving many groups across
Europe and outside
EUDET have ongoing EU project (FP6-I3) hosted by DESY - ends by end 2009.
In the neutrino area and flavour area specific detector R&D is foreseen or ongoing.
CERN has R&D activities in white paper, overlapping partly with (and participating in) the activities above.
Unless coordinated there will be a (large?) number of competing IA proposals from our community
Furthermore, there is clear need to improve contact between R&D groups in these areas and also use European infrastructures for these R&D activities are efficiently as possible (testbeams, irradiation facilities, integration areas, facilities with magnets or cryogenic infrastructures, etc)
Note: ESGARD have already decided to collect accelerator R&D in all the areas above (and CLIC) into one single IA application.
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FP7-Planning of calls and indicative budget
Total operational budget 1665 M€
Call 12007
Call 22007
Call 32008
Call 42008
Call 5 2009
Call 62010
Call 72012
Integrating activities
277 x x
e-Infrastructures 42 50 113 x x
Design studies 31 x
Construction – Support to the Preparatory Phase
147 x
Construction – Support to the Implementation Phase
RSFF (200 M€) + 130 M€
Policy Development and Programme Implementation
8 14 5 x x x
Total per call (M€) 228 64 282 113
R.Aleksans talk in ESGARD workshop
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EUDET/DESY (J.Mnich) EUDET runs until end 2009, nevertheless make plans for this IAcall (DS maybe would have been preferred but timing wrong)
Directions of interest for FP7: Hadron test beam ILC like testbeam timing structure (particle type not so important) DAQ Electronics (DSM)
Resources expected to be similar to EUDET Meeting in Paris 8-9.10
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ATLAS (N.Hessey)Activities (22 R&Ds ongoing – each with 5-10 groups): Several Inner Detector proposals (sensors, FE elec, modules, cooling,
powering, etc) LAr high rate Muon high rate Forward areas Infrastructures: Project Office – to document as built (technical coordination) GIF (muon irradiation facility) Testbeams w/magnet + irradiation Clean room plus bonding facilities, assembly areas
– Cooling plantsResources not given (but can be estimated for each R&D part). Both for ATLAS and CMS upgrade workshops typically draw 100150 – mostly active – participants
S.Stapnes 21
CMS (J.Nash)
R&D activities: ID parts similar to ATLAS Powering Radiation studies/simulation Track stub at lvl1 (lvl1 track trigger) Machine interface Muons and calos less critical to change than for ATLAS
Resources – R&D, 20% of CORE estimate for upgrade
(would be 30 MCHf)
Infrastructures:Testbeams and irradiations, cleanroom
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Neutrinos (NEUdet – A.Blondel)Detectors (costing similar to LHC experiments) – 2012-2021 (500 people)
JRA Work packages Test beam infrastructure (Radicioni) Photon detectors (near and far detectors) (Soler, Cervera) Cryogenic (liquid argon) detector studies (Rubbia) Silicon detectors for near detectors (Soler) Very large magnet development (NN)
Networking activities: (Cervera) (two NA, management, and:) putting it all together, co-ordintation of test beam, web master, etc.. common simulation and performance and cost evaluation framework work towards forming a
community consensus conception of hybrid detectors and combined test beam measurements link to industrial partners and other fields using similar detectors (LHC/LC)
Transnational access (one) access to test beam facilities
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Flavour (F.Forti)Several areas similar to ILC, but timing structure (luminosity) achallenge
Areas: Thin silicon Photo detection for PID Crystals for calorimeters (LSO for example) Large area muon … System aspects of large silicon systems Infrastructures: Beam structure, 4ns continuous Testbeams at CERN and Frascati
Interested in participating in IA (either alone or together) …
S.Stapnes 24
CERN (L.Linssen)Resources estimate given based on R&D included in white paper … covering 2008-2011 Focus on common developments: Radiation hard electronics and Common Building Block On detector power management Rad. hard optical links for experiments RD50 - silicon RD51 – micropattern (mentioned detector simulation tool – GARFIELD) Interconnection (hybridisation) Facilities and Components analysis for detector R&D
– GIF+PS+component analysis for gas systems Exploit multicore processes for simulation … Virtual technologies Must avoid too large overlap with SLHC-PP Infrastructures: Testbeams, irradiation facilities + GIF, cleanrooms, microelectronics, gas supply with gas analysis