Post on 25-Feb-2016
description
The Compressed Baryonic Matter Experimentat the Future Facility for Antiproton and Ion Research (FAIR)
Outline:
FAIR: future center for nuclear and hadron physics in Europe Compressed Baryonic Matter: physics and observables Technical challenges, time lines ...
Peter Senger
SIS 100 TmSIS 300 TmU: 35 AGeV p: 90 GeV
Structure of Nuclei far from Stability
Cooled antiproton beams up to 15 GeV:Charmonium Spectroscopy,Search for glueballs and hybrids,Hypernuclear physics, ...
Compressed Baryonic Matter
The FAIR layout
Key features:Generation of intense, high-quality secondary beams of rare isotopes and antiprotons.Two rings: simultaneous beams.
Ion and Laser Induced Plasmas: High Energy Density in Matter
States of strongly interacting matter
baryons hadrons partons
Compression + heating = quark-gluon plasma (pion production)
Neutron stars Early universe
Exploring the phase diagram of strongly interacting matter
CERN-SPS, RHIC, LHC: high temperature, low baryon densityGSI SIS300: moderate temperature, high baryon density
The critical end point
Ejiri et al.Fodor-Katz
Cross over
1st order transition
Mapping the QCD phase diagram with heavy-ion collisions
CBM physics:exploring the high density regionof the QCD phase diagram.
Search for• restoration of chiral symmetry• partonic matter at large μB • critical endpoint
Dense baryon-dominated matter
Meson-dominatedmatter
B 3-80 , T 130 MeV
Fundamental questions:
Equation-of-state at high densities: supernova dynamics, stability of neutron stars
In-medium hadron properties: chiral symmetry restoration, origin of hadron masses?
deconfinement
Diagnostic probes
CBM physics topics and observables 1. In-medium modifications of hadrons onset of chiral symmetry restoration at high B
measure: , , e+e- open charm (D mesons) 2. Strangeness in matter (strange matter?) enhanced strangeness production ? measure: K, , , , 3. Indications for deconfinement at high B anomalous charmonium suppression ? measure: J/, D softening of EOS measure flow excitation function 4. Critical point event-by-event fluctuations 5. Color superconductivity precursor effects ?
pn
++
K
e+
e-
p
Looking into the fireball …
… using penetrating probes:
short-lived vector mesons decaying into electron-positron pairs
Invariant mass of electron-positron pairs from Pb+Au at 40 AGeVCERES Collaboration S. Damjanovic and K. Filimonov, nucl-ex/0109017
≈185 pairs!
Statistical hadron gas modelP. Braun-Munzinger et al.
Nucl. Phys. A 697 (2002) 902
Experimental situation : Strangeness enhancement ?Experimental situation : Strangeness production
in central Au+Au and Pb+Pb collisions
New results from NA49 (CERN Courier Oct. 2003) SIS100300
SIS100300
central collisions 25 AGeV Au+Au 158 AGeV Pb+Pb
J/ multiplicity 1.5·10-5 1·10-3 beam intensity 1·109/s 2·107/sinteractions 1·107/s (1%) 2·106/s (10%)central collisions 1·106/s 2·105/sJ/ rate 15/s 200/s 6% J/e+e- (+-) 0.9/s 12/sspill fraction 0.8 0.25 acceptance 0.25 0.1J/ measured 0.17/s 0.3/s 1·105/week 1.8·105/week
J/ experiments: a count rate estimate10 50 120 210 Elab [GeV]
Charmed mesonsSome hadronic decay modes
D (c = 317 m):D+ K0+ (2.90.26%)D+ K-++ (9 0.6%)
D0 (c = 124.4 m):D0 K-+ (3.9 0.09%)D0 K-+ + - (7.6 0.4%)
D meson production in pN collisions
Measure displaced vertex with resolution of 30 μm !
Experimental challenges
107 Au+Au reactions/sec (beam intensities up to 109 ions/sec, 1 % interaction target)
determination of (displaced) vertices with high resolution ( 30 m)
identification of electrons and hadrons
Central Au+Au collision at 25 AGeV:URQMD + GEANT4
160 p 400 -
400 + 44 K+ 13 K-
The CBM Experiment
Radiation hard Silicon pixel/strip detectors in a magnetic dipole field Electron detectors: RICH & TRD & ECAL: pion suppression up to 105
Hadron identification: RPC, RICH Measurement of photons, π0, η, and muons: electromagn. calorimeter (ECAL) High speed data acquisition and trigger system
CBM Collaboration : 39 institutions, 14 countriesCroatia: RBI, Zagreb
Cyprus: Nikosia Univ. Czech Republic:Czech Acad. Science, RezTechn. Univ. Prague France: IReS Strasbourg
Germany: Univ. Heidelberg, Phys. Inst.Univ. HD, Kirchhoff Inst. Univ. FrankfurtUniv. Mannheim Univ. MarburgUniv. MünsterFZ RossendorfGSI Darmstadt
Russia:CKBM, St. PetersburgIHEP ProtvinoINR TroitzkITEP MoscowKRI, St. PetersburgKurchatov Inst., MoscowLHE, JINR DubnaLPP, JINR DubnaLIT, JINR DubnaObninsk State Univ.PNPI GatchinaSINP, Moscow State Univ. St. Petersburg Polytec. U.
Spain: Santiago de Compostela Univ. Ukraine: Shevshenko Univ. , KievUniv. of Kharkov
Hungaria:KFKI BudapestEötvös Univ. Budapest
Korea:Korea Univ. SeoulPusan National Univ.
Norway:Univ. Bergen
Poland:Krakow Univ.Warsaw Univ.Silesia Univ. Katowice Portugal: LIP CoimbraRomania: NIPNE Bucharest
FAIR cost (M€)Total: 675
Buildings: 225.5 SIS100: 70.1 SIS200: 39.6 Coll. Ring: 45.0 NESR: 40.0 HESR: 45.0e-ring: 15.0 Beamlines: 21.0 Cryo, etc: 44.1
SFRS: 40.7CBM: 27.0AP: 8.7Plasma phys.: 8.0p-linac: 10.0PANDA: 28.4pbar targ.: 6.9
FAIR milestonesOct. 2001 : Submission of the Conceptual Design Report
Nov. 2002: Positive evaluation report of the German science council
Feb. 2003: Project approved by the German federal government (170 M€ foreign contributions requested)
Jan. 2004: Letters of intent submitted
Feb. 2004: 1. Meeting of Internat. Steering Committee (12 nations)
June 2004: Evaluation of the LOI,s by PACs
Jan 2005: Submission of Technical Reports
2005 2006 2007 2008 2009 2010 2011 2012 2013 2014
SIS18 Upgrade 70 MW Connection
Proton-Linac
TDM#
SIS100 Transfer Line SIS18-SIS100
High Energy Beam Lines
RIB Prod.-Target, Super-FRSRIB High+Low Energy Branch
Antiproton Prod.-TargetCR-Complex
HESR & 4 MV e- –CoolingNESR
SIS200*8 MV e- –Cooling
e-A Collider
SIS100/200 Tunnel, SIS Injection+Extraction+Transfer
Transfer Buildings/Line Super-FRS,Auxiliary Bldgs., Transfer Tunnel to SIS18,Building APT, Super-FRS, CR-ComplexRIB High+Low Energy Branch,
HESR ( ground level),NESR, AP-cave,e-A Collider, PP-cave
CBM-Cave, Pbar-Cave, Reinjection SIS100
Civil Construction
Civil Construction 1
Civil Construction 3
Civil Construction 2
Civil Construction 4
I
IV
III
V
II
Concept for staged Construction of FAIR
2,7x1011 /s 238U28+ (200 MeV/u) 5x1012 protons per puls
1x1011/s 238U28+ (0.4-2.7GeV/u) ->RIB (50% duty cycle)
2.5x1013 p (1-30 GeV)3-30 GeV pbar->fixed target10.7 GeV/u 238U -> HADES*
1x1012/s 238U28+
100% duty cyclepbar cooledp (1-90 GeV)
35 GeV/u 238U92+
NESR physicsplasma physics
Experiment Potential
#Construction Tunnel Drilling Machine
General Planning
Civil Construction Production and Installation *SIS200 installation during SIS100 shut down
MIMOSA IV
IReS / LEPSI Strasbourg
Design of a Silicon Pixel detector
Design goals: • low materal budget: d < 200 μm • single hit resolution < 20 μm• radiation hard (dose 1015 neq/cm2)• fast read out
Silicon Tracking System: 7 planar layers of pixels/strips.Vertex tracking by two first pixel layers at 5 cm and 10 cm downstream target
Roadmap:R&D on Monolithic Active Pixel Sensors (MAPS)• pitch 20 μm• thickness below 100 μm • single hit resolution : 3 μm• Problem: radiation hardness and readout speed
Fallback solution: Hybrid detectors
Hit rates for 107 minimum bias Au+Au collisions at 25 AGeV:
Experimental conditions
Rates of > 10 kHz/cm2 in large part of detectors ! main thrust of our detector design studies
Design of a high rate RPCDesign goals: • Time resolution ≤ 80 ps• High rate capability up to 25 kHz/cm2• Efficiency > 95 %• Large area 150 m2• Long term stability
Prototype test:detector with plastic electrodes(resistivity 109 Ohm cm.)P. Fonte, Coimbra
“Trajectories” (3 fluid hydro)
Hadron gas EOS
Ivanov & Toneev
Calculations reproduce freeze-out conditions
30 AGeV trajectoryclose to the critical endpoint
Mapping the QCD phase diagram with heavy-ion collisions
B 6 0
B 0.3 0
baryon density: B 4 ( mT/2)3/2 x
[exp((B-m)/T) - exp((-B-m)/T)] baryons - antibaryons
P. Braun-Munzinger
SIS300
C. R. Allton et al, hep-lat 0305007
Lattice QCD : maximal baryon number density fluctuations at TC for q = TC (B 500 MeV)
Design of a fast TRD
Design goals: e/π discrimination of > 100 (p > 1 GeV/c)• High rate capability up to 150 kHz/cm2
• Position resolution of about 200 μm• Large area ( 500 m2, 9 layers)
Roadmap:Outer part: ALICE TRD Inner part: • GEM/MICROMEGAS readout chambers• Straw tube TRT (ATLAS) • Fast read-out electronics
CBM R&D working packages Feasibility, Simulations
D Kπ(π)GSI Darmstadt, Czech Acad. Sci., RezTechn. Univ. Prague
,ω, e+e-Univ. KrakowJINR-LHE Dubna
J/ψ e+e-INR Moscow
Hadron ID Heidelberg Univ,Warsaw Univ.Kiev Univ. NIPNE BucharestINR Moscow
GEANT4: GSI
TrackingKIP Univ. HeidelbergUniv. MannheimJINR-LHE Dubna
Design & constructionof detectors
Silicon PixelIReS StrasbourgFrankfurt Univ.,GSI Darmstadt,RBI Zagreb,Univ. Krakow
Silicon StripSINP Moscow State U.CKBM St. PetersburgKRI St. Petersburg
RPC-TOFLIP Coimbra, Univ. Santiago de Com.,Univ. Heidelberg,GSI Darmstadt,Warsaw Univ.NIPNE BucharestINR MoscowFZ RossendorfIHEP ProtvinoITEP Moscow
Fast TRDJINR-LHE, DubnaGSI Darmstadt,Univ. MünsterINFN Frascati
Straw tubesJINR-LPP, DubnaFZ RossendorfFZ JülichTech. Univ. WarsawECAL ITEP Moscow GSI DarmstadtUniv. Krakow
RICH IHEP Protvino GSI Darmstadt
Trigger, DAQKIP Univ. HeidelbergUniv. MannheimGSI DarmstadtJINR-LIT, DubnaUniv. BergenKFKI BudapestSilesia Univ. KatowiceUniv. Warsaw
MagnetJINR-LHE, DubnaGSI Darmstadt
AnalysisGSI Darmstadt,Heidelberg Univ,
Data Acquis.,Analysis
Mapping the QCD phase diagram with heavy-ion collisions
B 6 0
B 0.3 0
Net baryon density: B 4 ( mT/2)3/2 x
[exp((B-m)/T) - exp((-B-m)/T)] baryons - antibaryons
P. Braun-Munzinger
SIS300