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Report from the Detector R&D Liaisons
Jan Strube (Tohoku University) / Maxim Titov (CEA Saclay)
*Aerial view at night, Chicago, Illinois
AWLC, Fermilab, May 12 - 16, 2014
LC DETECTOR R&D LIAISONS: Maxim Titov (Liaison), Jan Strube (Deputy Liaison)
CHARGE: The detector R&D liaison ensures productive communication between the LCC Physics and Detectors Executive Board and detector R&D groups. The liaison is a member of the Executive Board and communicates relevant information from the Executive Board to detector R&D groups and vice versa.
The liaison is in contact with all detector R&D groups relevant to linear colliders to keep track of the overall detector R&D efforts conducted or planned for linear colliders and to periodically compile summaries of the efforts.
There are many forms of Detector R&Ds relevant to LC:
‘Large collaborations’ such as CALICE, LCTPC, FCAL…
Collection of many efforts such as the vertexing R&Ds
Individual group R&D activities
Efforts currently not directly included in the concept groups (ILD, SiD, CLIC), which may become important for LC in future
Major accomplishments during the last few years: ILC: June 2013 - Detailed Baseline Design (DBD) Report in ILC TDR:http://www.linearcollider.org/ILC/Publications/Technical-Design-ReportDBD is not the TDR which is the next goal: Major Engineering efforts and More R&D are still needed
CLIC: 2012 Conceptual Design Report: http://clic-study.org/accelerator/CLIC-ConceptDesignRep.phpStarting from ILC Detector Concepts: redesign forward region (higher bkg) and calorimetry (higher energy jets) precise hit timing ~10 ns (vertex) and ~ 1 ns (calo)
Successful cooperation between ILC and CLIC Synergy in Detector R&D Studies
Two approaches (ILD and SiD) – Similar Concepts, Different Realizations
ILDSiD
CLIC
CALICEgroups
LCTPC groups
CMOS
GOAL: Shape up-to-date efforts report of the LC Detector R&Ds (this is not an attempt to control different R&Ds, rather collection of information for people to use !)
Update of the R&D developments since ILC DBD and CLIC CDR Summarize contributions of individual group R&D efforts Aim for document of < 100 pages Timescale – Linear Collider Workshop in Belgrade (Oct. 2014) could help new groups to learn about the current landscape of the R&D activities
ChronopixelDEPFET
Concentrate on the R&D activities for the ILD/ SiD Concepts Discuss synergy between ILC and CLIC developments Group individual R&Ds based on vertexing, tracking, calorimetry, …
Individual ILC / CLIC R&D Groups are asked to provide (max. 1-2) summary, specifically addressing the following points:
Major R&D efforts (past and present) and recent developments since ILC DBD (with publications/references to major results);
Engineering challenges;
Detector R&D plans for the coming years;
List of collaborating institutes (contributing to this R&D technology);
Perspectives of this R&D for applications beyond the ILC (with references if technology is already used in the other projects)
R&D Technology
Participating Institutes
Technical Summary
Achieved Results /
Milestones :
Future Activities :
ILC DBD or CLIC CDR Concept:
Past Developments (not included into ILC DBD and CLIC CDR) or New/Emerging R&Ds:
and will be asked to summarize major activities in the table:
Major R&D efforts (past and present) and recent developments since ILC DBD (with publications/references to major results)
short introduction into technology and summary of the new results since DBD/CDR. Goal is to include also earlier R&Ds developments, in particular, those currently not directly adopted by the ILD, SiD or CLICdp detector concepts (and thus not included in the DBD or CDR) and/or to describe new/emerging R&Ds
Engineering challenges (probably the most challenging question)
most of the ILC detector technologies are mature enough and are ready to go. Engineering aspects are less advanced and need some more years before finalized. Engineering challenges are related to the system integration aspects (e.g., minimization of the material amount in the vertex system to achieve flavor tagging requirements). Since this report will serve as the “entrance point” to the new groups, it would be beneficial if new groups will decide to contribute to the engineering aspects, and not only to the basic detector R&D efforts.
Detector R&D plans for the coming years;List of collaborating institutes (contributing to this R&D technology)
goal is to summarize individual group plans (if sufficient funding is available), including engineering challenges
Perspectives of this R&D for applications beyond the ILC (with references if technology is already used in the other projects)
number of the LC R&D developments has been successfully used in other HEP experiments and its extend and the number of spin-offs continue to grow (some groups continue detector R&Ds jointly for ILC and other HEP projects). These synergies are important to advance the image of the LC Detector R&D for the HEP field, in general.
THIS IS A CALL TO SUBMIT YOUR CONTRIBUTION to the “Detector R&D Liaison Report“ please send your inputs toJan Strube ([email protected]), Maxim Titov (
Some R&D groups have already been contacted and asked to answer questionnaire
~ 40 % of groups already provided their summaries (some groups sent us also 50-100 pages documents prepared for review panels or funding agencies)
Too much variations in the received inputs need substantial editing All groups will be able to see/comment on the report (before it will become public). The goal is to have such "efforts review" document ready for Belgrade LCC 2014 meeting.
Technology Institute Contact name
ILC Pixel Vertex R&Ds:
CMOS MAPS IPHC Strasbourg M. Winter
DEPFET MPI MunichIFIC Valencia
L. AndricekM. Vos
FPCCD KEK Y. Sugimoto
3D-pixel and integration
FNAL R. Lipton
Chronopixel Univ. Oregon N. Sinev/. Brau
SOI KEK Y. Arai
CLIC Pixel Vertex R&Ds:
Hybrid Sensor +ASICHV-CMOS + ASIC
CERN L. Linssen / D. Dannheim
Si-Tracking Electronics R&Ds:
LSTFE readout ASIC
SCIPP, UCSC B. Schumm
KPIX readout ASIC(also for ECAL)
SLAC M. Breidenbach
DEPFET for Belle II
CLIC (hybrid pixels):thin Si-sensor
+Timepix
CMOS for STAR
Technology Institute Contact
GEM- based readout:
Laser-etched GEM (Asian GEMs):
KEK
Univ. Saga
K. Fujii/T. MatsudaA. Sugiyama
Wet-etched GEMs
DESYRWTH Aachen
T. BehnkeS. Roth
Micromegas-based readout:
Resistive MM with dispersive anode
CEA Saclay
Carleton
P. Colas/D. AttieA. Belletive
GEM or Micromegas + Timepix pixel readout:
GEM + pixel BonnSiegenFreiburg
J. KaminskiI. FleckM. Schumacher
InGrid: NIKHEFBonn CEA Saclay
J. TimmermansJ. KaminskiD. Attie
Other aspects:
Mechanics CornellKansas
D. PetersonG. Wilson
Electronics Lund L. Jonssonhttp://ecfa-dp.desy.de/
~ 70 pages
Technology Institute Contact
ILC ECAL R&Ds:
Silicon ECAL LLR
LALKyushu Univ./Tolyo Univ.Univ. Oregon
J.-C. Brient/ V. BoudryR. PoeschlK. Kawagoe/T. YoshiokaD. Strom
MAPS ECAL IC London P. Dauncey
Sci ECAL Shinshu University
T. Takeshita
ILC HCAL (AHCAL) R&Ds:
Sci AHCAL DESY F. Sefkow
ILC HCAL ((s)DHCAL) R&Ds:
RPC DHCAL Argonne (ANL) J. Repond
RPC sDHCAL IPNL Lyon I. Laktineh
GEM DHCAL Univ. Arlington A. White
MM sDHCAL LAPP Annecy M. Chefdeville
AHCAL
Technology Institute Contact
ILC Forward Calorimeter R&Ds:
LumiCal / BeamCal
DESY (on behalf of the 15 FCAL institutes)
W. Lohnmann
Other technology options for LC calorimeter:
Dual-readout calorimetry
On behalf of the 11 RD52 institutes
J. Hauptmann
ECFA Detector R&D Panel: http://ecfa-dp.desy.de
~ 70 pages
Technology Institute Contact
CLIC HCAL R&Ds:
Sci AHCAL CERN, MPI, DESY / Univ. Hamburg
F. SimonL. LinssenF. Sefkow
RPC DHCAL CERN, ANL L. LinssenJ. Repond
CLIC FCAL R&Ds:
FCAL hardware
CERN L. Linssen
Synergies between CLIC - ILC:
FCAL (BeamCal) sensors:
Aim is to deliver a “coherent summary”(LC Detector R&D Efforts Review) group individual R&Ds (based on technology) and summarize them in the tables