1 Conceptual design adopts state-of-the-art silicon sensor techniques (compare ATLAS/CMS/ALICE inner tracker layers, BaBar tracking of B mesons). Design.

Slides:

Advertisements

Similar presentations

Proposal for a new design of LumiCal R. Ingbir, P. Ruzicka, V. Vrba October 07 Malá Skála.

Advertisements

ATLAS SCT Endcap Detector Modules Lutz Feld University of Freiburg for the ATLAS SCT Collaboration Vertex m.

C. Schwarz Physics with Antiprotons - Detector - Detector requirements Overview of the detector concept Detector components Trigger Costs.

N-XYTER Hybrid Developments Christian J. Schmidt et al., GSI Darmstadt JINR, Dubna, Oct. 15 th 2008.

Using the EUDET pixel telescope for resolution studies on silicon strip sensors with fine pitch Thomas Bergauer for the SiLC R&D collaboration 21. May.

A Silicon Disk Tracker in forward direction for STAR News since November 2000 Physics Capabilities capabilities Requirements / Potential Technologies Possible.

LHC Experiments at Liverpool E2V Visit – Nov 2005 Introduction Si Technology Upgrade/Maintenance Summary.

PHENIX Vertex Tracker Atsushi Taketani for PHENIX collaboration RIKEN Nishina Center RIKEN Brookhaven Research Center 1.Over view of Vertex detector 2.Physics.

Module Production for The ATLAS Silicon Tracker (SCT) The SCT requirements: Hermetic lightweight tracker. 4 space-points detection up to pseudo rapidity.

The LHCb Inner Tracker LHCb: is a single-arm forward spectrometer dedicated to B-physics acceptance: (250)mrad: The Outer Tracker: covers the large.

Daniela Calvo INFN – Sezione di Torino

The BTeV Tracking Systems David Christian Fermilab f January 11, 2001.

STS Simulations Anna Kotynia 15 th CBM Collaboration Meeting April , 2010, GSI 1.

D. Lissauer, BNL. 1 ATLAS ID Upgrade Scope R&D Plans for ATLAS Tracker First thoughts on Schedule and Cost.

1 Jim Thomas - LBL STAR Inner Tracking Upgrades with an emphasis on the Heavy Flavor Tracker presented by Jim Thomas Lawrence Berkeley Laboratory 11 /

High-resolution, fast and radiation-hard silicon tracking station CBM collaboration meeting March 2005 STS working group.

Pixel hybrid status & issues Outline Pixel hybrid overview ALICE1 readout chip Readout options at PHENIX Other issues Plans and activities K. Tanida (RIKEN)

Ooo Performance simulation studies of a realistic model of the CBM Silicon Tracking System Silicon Tracking for CBM Reconstructed URQMD event: central.

1 CLAS12/Central Tracker review. Saclay 12/09 Stéphan AUNE Central Tracker review Micromegas central & forward tracker  R&D and prototypes  CAD implantation.

ATLAS Forward Detector Trigger ATLAS is presently planning to install forward detectors (Roman Pot system) in the LHC tunnel with prime goal to measure.

Installation and operation of the LHCb Silicon Tracker detector Daniel Esperante (Universidade de Santiago de Compostela) on behalf of the Silicon Tracker.

Design and development of micro-strip stacked module prototypes for tracking at S-LHC Motivations Tracking detectors at future hadron colliders will operate.

A Silicon vertex tracker prototype for CBM Material for the FP6 Design application.

2 Silicon pixel part Done and to be written Written! Under way To be done Introduction 1.Hybrid Pixel Assembly Concept 2.Silicon sensor 1.First thinned.

LHCb VErtex LOcator & Displaced Vertex Trigger

Thin Silicon R&D for LC applications D. Bortoletto Purdue University Status report Hybrid Pixel Detectors for LC.

PHENIX Silicon Vertex Tracker. Mechanical Requirements Stability requirement, short and long25 µm Low radiation length

Technology Overview or Challenges of Future High Energy Particle Detection Tomasz Hemperek

p-on-n Strip Detectors: ATLAS & CMS

Performance simulations with a realistic model of the CBM Silicon Tracking System Silicon tracking for CBM Number of integration components Ladders106.

11 June 2015 Thomas Bergauer (HEPHY Vienna) Belle II SVD beam Test SPS 2015 SPS users meeting.

- Performance Studies & Production of the LHCb Silicon Tracker Stefan Koestner (University Zurich) on behalf of the Silicon Tracker Collaboration IT -

M. Deveaux, CBM-Collaboration-Meeting, 25 – 28. Feb 2008, GSI-Darmstadt Considerations on the material budget of the CBM Micro Vertex Detector. Outline:

1 FPCCD VTX Work Plan Y. Sugimoto 2010/1/22. 2 FPCCD: Features and R&D issues (1/2) Small pixel size (~5  m) –Sensor development Small size chip; ~6mm.

20/12/2011Christina Anna Dritsa1 Design of the Micro Vertex Detector of the CBM experiment: Development of a detector response model and feasibility studies.

On a eRHIC silicon detector: studies/ideas BNL EIC Task Force Meeting May 16 th 2013 Benedetto Di Ruzza.

SiD Vertex Detector Mechanical R&D (May Apply to Other Concepts) Bill Cooper Fermilab.

The LHCb Vertex Locator Lars Eklund LHCb VELO Group of the LHCb Collaboration CERN (Geneva), EPFL (Lausanne), NIKHEF (Amsterdam), University of Glasgow,

8/12/2010Dominik Dannheim, Lucie Linssen1 Conceptual layout drawings of the CLIC vertex detector and First engineering studies of a pixel access/insertion.

FPCCD VTX Work Plan Y. Sugimoto 2010/1/22. FPCCD: Features and R&D issues (1/2) Small pixel size (~5  m) –Sensor development Small size; ~6mm x 6mm Full.

Rene BellwiedSTAR Tracking Upgrade Meeting, Boston, 07/10/06 1 ALICE Silicon Pixel Detector (SPD) Rene Bellwied, Wayne State University Layout, Mechanics.

10 September 2010 Immanuel Gfall (HEPHY Vienna) Belle II SVD Upgrade, Mechanics and Cooling OEPG/FAKT Meeting 2010.

A. Rivetti VIPS workshop-Pavia, April 23rd, 2010 The PANDA Microvertex Detector: Present Design and Opportunities for 3D Integration Technologies Angelo.

Peculiarities of the PANDA experimental setup Overview of the PANDA detector Particle Tracking: PANDA MVD Particle Identification: PANDA DIRCs Particle.

The BTeV Pixel Detector and Trigger System Simon Kwan Fermilab P.O. Box 500, Batavia, IL 60510, USA BEACH2002, June 29, 2002 Vancouver, Canada.

0 Characterization studies of the detector modules for the CBM Silicon Tracking System J.Heuser 1, V.Kyva 2, H.Malygina 2,3, I.Panasenko 2 V.Pugatch 2,

Manoj B. Jadhav Supervisor Prof. Raghava Varma I.I.T. Bombay PANDA Collaboration Meeting, PARIS – September 11, 2012.

The SuperB Silicon Vertex Tracker Abstract : The SuperB project aims to build an asymmetric e+ - e- collider capable of reaching.

Atlas SemiConductor Tracker final integration and commissioning Andrée Robichaud-Véronneau Université de Genève on behalf of the Atlas SCT collaboration.

1 J.M. Heuser − STS R&D Johann M. Heuser, GSI CBM-STS Project Leader Meeting on Experiment with external HI beams of the Nuclotron-M JINR, 4 February 2011.

De Remigis The test has been accomplished with an SLVS signal, since that was chosen for the serial communication between the readout and the optical converter.

Status of the PANDA MVD Project

The Jülich Digital Readout System for PANDA Developments

GSI, for the CBM Collaboration

 Silicon Vertex Detector Upgrade for the Belle II Experiment

Technical Design for the Mu3e Detector

IOP HEPP Conference Upgrading the CMS Tracker for SLHC Mark Pesaresi Imperial College, London.

Hybrid Pixel R&D and Interconnect Technologies

Silicon Pixel Detector for the PHENIX experiment at the BNL RHIC

Simulated vertex precision

The SuperB Silicon Vertex Tracker

Work packages status in Torino and perspectives

Valerio Re (INFN-Pavia) on behalf of the RD53 collaboratios

Pixel DAQ and Trigger for HL-LHC

SVT detector electronics

Special Considerations for SIDIS

The LHCb Level 1 trigger LHC Symposium, October 27, 2001

Setup for testing LHCb Inner Tracker Modules

SVT detector electronics

Perugia SuperB Workshop June 16-19, 2009

Presentation transcript:

1 Conceptual design adopts state-of-the-art silicon sensor techniques (compare ATLAS/CMS/ALICE inner tracker layers, BaBar tracking of B mesons). Design features: Minimum of 4 space points forward of 90° Barrel and forward disk structures Pixels and double-sided strips Smallest possible inner radius Fast and untriggered readout The Micro-Vertex Detector of PANDA

2 Micro-Vertex Detector 10 cm

3 The PANDA Micro-Vertex Detector Experimental task list: Precision identification of D mesons by fast reconstruction Measurement of long-lived baryons and mesons (open charm and strangeness) Seeding for tracking device through high time-resolution and precise spatial information close to the vertex point Limited particle identification

4 The PANDA Micro-Vertex Detector Contributors and Competence: TU Dresden (  group moving to U Bonn): Strip sensor tests, layout, mechanics, readout for strip sensor part. ELBE electron accelerator, ELSA electron accelerator, neutron generators, neutron sources, skilled electronics lab.

5 The PANDA Micro-Vertex Detector Contributors and Competence: FZ Jülich: Pixel detector readout, mechanics. COSY proton synchrotron, very skilled mechanics and engineering infrastructure, very skilled electronics infrastructure, experience in silicon detector technology.

6 The PANDA Micro-Vertex Detector Contributors and Competence: INFN Torino: Pixel sensor readout and tests, layout, mechanics, readout for pixel sensors, sensor R&D. Long-term involvement in CERN LHC experiments, pixel sensor development at all stages, in particular readout, design of front ends on chip level, practical experience in the setup and operation of large silicon detector arrays.

7 The PANDA Micro-Vertex Detector Cooperation and common interest with: CBM/GSI: Technology for strip detector readout due to very similar requirements and challenges  n-Xyter development for a strip sensor frontend with triggerfree readout. PANDA hypernuclei experiment (U Mainz). Sensor foundries (CIS, ITCirst). FH Aachen (lightweight frame)

8 Conceptual design adopts state-of-the-art silicon sensor techniques (ATLAS/CMS/ALICE inner tracker layers) Design features: 5 layers forward of 90° Barrel and forward disk structures Pixels and double-sided strips Smallest possible inner radius Fast readout Micro-Vertex Detector p beam 10 cm pellet or cluster jet target

9 Detector Optimization in Simulations

Micro-Vertex Detector - Simulations rate / ^MHz Calculations of various reaction channels, UrQMD, DPM of p on p and nuclear targets - rate estimates (data rates → electronics!) - reconstruction → resolution → detector layout - mechanics very anisotropic load! 10

Micro-Vertex Detector - Simulations 11

Micro-Vertex Detector - Simulations Radiation load maps pp at 10 GeV/c pPb at 4.05 GeV/c 12

13 Detector Optimization in Simulations

14 Mechanical Model – v1.0

15 Micro-Vertex Detector – Building Blocks Two compact layers of pixel sensors: Barrel structures Forward walls integrated in the disks Two layers of pixel sensors: Barrel structures from double-sided rectangular sensors Forward pizzas from trapezoidal sensors Additional pizzas further downstream to supplement forward tracking ► total of four disks

16 Micro-Vertex Detector - Pixels PANDA optimized pixel layout: Small pixel cells – 100 x 100 µm 2 Specialized custom hybrid features:-.13 µ technology - ToT to retain (some) energy information - fast handling for high data rates - “untriggered” readout of data - rad hard within “typical” limits - minimum material load  sensor technology

17 TOPIX ASIC.13 µ technology pixel size 100x100 µm 2 high readout capability sufficient buffering to operate without trigger ToT Sensors on EPI: < 100 µm thickness

18 Readout Prototype Versatile digital readout board First tests with ATLAS FE Digital part can be adapted to TOPIX

19 Mechanics cooling, cables, frames CARBON FIBER 0,2 mm FOAM 1 mm PIXEL + CABLE 0,2 mm Overlapping layout Turbo layout Work on mechanical layout Scenarios for cooling: - Cooling liquid (water or C6F14) - Evaporative cooling system

20 Micro-Vertex Detector - Strips PANDA strip layers: Substitute strips for pixels to keep number of space points with less traversed material where possible Use standard solutions where possible features:- pitch of 50 – 100 µm - double-sided sensors, 200 µm thick - need specialized solution for front-end to achieve untriggered readout  synergy CBM / PANDA on n-XYTER - minimum possible thermal load

21

22 Strip Sensors – Test Station sensor sensor “telescope” ITCirst, 20x20 mm 2 50 µm pitch

23 Strip Sensors – Test Station sensor “telescope” ITCirst, 20x20 mm 2 50 µm pitch Readout of signals: front end APV25 S1 50 µm

24 Strip Sensors – Test Station

25  single-side readout 1 readout slice / 128 channels (one APV 25) Strip Sensors – Test Station

26 Strip Sensors – Test Station

27 PANDA MVD Summary PANDA will greatly benefit from a state-of-the-art silicon tracking device. PANDA-specific challenges: very compact design, high and anisotropic data rates, free-running DAQ concept (untriggered readout), material budget. PANDA-specific solutions needed: pixel readout, strip front-end (synergy with other FAIR experiments), compact arrangement around fixed target.

28 PANDA MVD Summary (II) Silicon detector development uses and drives key technologies of solid state industry (e.g. flip chip in 130 nm rad-hard) The PANDA MVD project suffers from a lack in qualified contrbutors, in particular in the strip part, more specifically in the critical forward disk part. Russian groups interested in the PANDA MVD have had great impact in detector developments of large scale experiments such as D0. Their bid to assume a leading role in the PANDA MVD project in a very critical and as of yet unsolved detector region will have great impact and will be highly welcomed.