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Brookhaven Science Associates The Future of RHIC Quark Matter 2005, Budapest Samuel Aronson, BNL August 8, 2005 ► Past & present – 2000 - 2005 ► Near-term future – 2006 - 2012 ► Longer-term future – 2013 - 2020 Quark Matter 2005, Budapest Samuel Aronson, BNL August 8, 2005 ► Past & present – 2000 - 2005 ► Near-term future – 2006 - 2012 ► Longer-term future – 2013 - 2020
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Brookhaven Science Associates Quark Matter 2005, Budapest 2 STAR 7 coupled accelerators Nucleus –nucleus collider from 20- 200GeV/nucleon Symmetric or asymmetric species Polarized p-p collisions up to 0.5TeV Both capabilities unique world-wide
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Brookhaven Science Associates Quark Matter 2005, Budapest 3 RHIC – a Uniquely Flexible High Luminosity Collider (Nucleon-pair luminosity A 1 A 2 L allows comparison of different species) Luminosity increased by 2 orders of magnitude in 4 years. RHIC nucleon-pair luminosity delivered to PHENIX
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Brookhaven Science Associates Quark Matter 2005, Budapest 4 Integrated luminosity 100 GeV/u *=0.85m (0.89m) *=2.6m *=3.0m Cu-cu cross section measured at 2.6 barn access + snowstorm power dip+ access access + equipment failures calendar time at store: 52%
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Brookhaven Science Associates Quark Matter 2005, Budapest 5 Delivered Luminosity (Physics Weeks) Summary of RHIC Runs 1-5
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Brookhaven Science Associates Quark Matter 2005, Budapest 6 RHIC Program Accomplishments ► Five spectacularly successful annual runs Physics discoveries: a new state of matter, “perfect liquid” Scores of refereed papers, thousands of citations Machine performance meeting and exceeding goals ► Recently published peer-reviewed retrospectives on the first 3 years of heavy ion physics Nuclear Physics A757 (in print today 8 August 2005) Online Where are we in the discovery phase? ► Large new Au+Au and Cu+Cu samples (Runs 4 & 5) ► Many new results from these here in Budapest ► Five spectacularly successful annual runs Physics discoveries: a new state of matter, “perfect liquid” Scores of refereed papers, thousands of citations Machine performance meeting and exceeding goals ► Recently published peer-reviewed retrospectives on the first 3 years of heavy ion physics Nuclear Physics A757 (in print today 8 August 2005) Online Where are we in the discovery phase? ► Large new Au+Au and Cu+Cu samples (Runs 4 & 5) ► Many new results from these here in Budapest http://www.sciencedirect.com/science/journal/03759474
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Brookhaven Science Associates Quark Matter 2005, Budapest 7 DiscoveriesDiscoveries ► We’ve learned we can do definitive studies of QCD at very high energy density in the laboratory! ► These measurements tell us the following about the matter produced at RHIC: Energy density > 15 GeV/fm 3, T ~ 200 MeV ► Sufficient to induce phase transitions ► Consistent with production from initial state with gluon saturation Extraordinary parton energy loss ► ~Opaque to partons, ~transparent to leptons and photons Thermalizes extremely rapidly, highly collective motion ► Consistent with zero viscosity hydrodynamic models ► “Perfect liquid” Consistent with a strongly coupled plasma of quarks & gluons ► We’ve learned we can do definitive studies of QCD at very high energy density in the laboratory! ► These measurements tell us the following about the matter produced at RHIC: Energy density > 15 GeV/fm 3, T ~ 200 MeV ► Sufficient to induce phase transitions ► Consistent with production from initial state with gluon saturation Extraordinary parton energy loss ► ~Opaque to partons, ~transparent to leptons and photons Thermalizes extremely rapidly, highly collective motion ► Consistent with zero viscosity hydrodynamic models ► “Perfect liquid” Consistent with a strongly coupled plasma of quarks & gluons
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Brookhaven Science Associates Quark Matter 2005, Budapest 8 A vision of the future of RHIC: “QCDLab” ► Discoveries at RHIC Compelling QCD questions: The nature of confinement The structure of quark-gluon matter above T C The low-x and spin structure of hadronic matter ► Compelling questions evolution of the Facility 10-fold increase in luminosity (to 40 x design) ► e-cooling @ full energy New detector capabilities 50-fold increase in lattice gauge computing power applied to finite temperature QCD eRHIC: e-A and polarized e-p collisions, new detector ► Discoveries at RHIC Compelling QCD questions: The nature of confinement The structure of quark-gluon matter above T C The low-x and spin structure of hadronic matter ► Compelling questions evolution of the Facility 10-fold increase in luminosity (to 40 x design) ► e-cooling @ full energy New detector capabilities 50-fold increase in lattice gauge computing power applied to finite temperature QCD eRHIC: e-A and polarized e-p collisions, new detector RHIC II
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Brookhaven Science Associates Quark Matter 2005, Budapest 9 Compelling questions ► The nature of confinement What is the nature of the phase transition? Is chiral symmetry restored? ► The structure of quark-gluon matter above T C How does the thermodynamic character of the collision evolve so rapidly from the initial state? What are the properties of the medium? ► The low-x and spin structure of hadronic matter Is the initial state a Color Glass Condensate? What is the spin structure and dynamics inside the proton? ► The nature of confinement What is the nature of the phase transition? Is chiral symmetry restored? ► The structure of quark-gluon matter above T C How does the thermodynamic character of the collision evolve so rapidly from the initial state? What are the properties of the medium? ► The low-x and spin structure of hadronic matter Is the initial state a Color Glass Condensate? What is the spin structure and dynamics inside the proton?
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Brookhaven Science Associates Quark Matter 2005, Budapest 10 Key measurements ► Hard probes (high p T, heavy quarks): sensitive to how the medium is created jets hidden charm & bottom open charm & bottom ► Electromagnetic probes (real & virtual s): information about the medium’s early properties Low-mass e + e − pairs Thermal radiation ► Polarized protons W-production at s=500GeV ► Hard probes (high p T, heavy quarks): sensitive to how the medium is created jets hidden charm & bottom open charm & bottom ► Electromagnetic probes (real & virtual s): information about the medium’s early properties Low-mass e + e − pairs Thermal radiation ► Polarized protons W-production at s=500GeV STAR Preliminary
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Brookhaven Science Associates Quark Matter 2005, Budapest 11 Near and mid term: 2006-2012 ► The big science questions for the field in this period are clear ► The bulk of US heavy ion effort will be directed to evolving and operating RHIC ► LHC will begin to produce results some time in this period ► The big science questions for the field in this period are clear ► The bulk of US heavy ion effort will be directed to evolving and operating RHIC ► LHC will begin to produce results some time in this period
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Brookhaven Science Associates Quark Matter 2005, Budapest 12 Upgrades High T QCD…. QGP SpinLow-x PHENIX e+e- heavy jet quarkonia flavor tomog. flavor tomog. W ΔG/G Hadron blind detector Vertex Tracker Muon Trigger Forward cal. (NCC) X X X O O O O O O O XXOOX STAR Time of Flight (TOF) MicroVtx (HFT) Forward Tracker Forward Cal (FMS) DAQ 1000 O X O O X O X X X X O O X X O X X X O O O O XO RHIC Luminosity O O X X O O O X upgrade critical for success O upgrade significantly enhances program A. Drees RHIC Upgrade: overview
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Brookhaven Science Associates Quark Matter 2005, Budapest 13 FY 2006 FY 2007 FY 2008 FY 2009 FY 2010 FY 2011 FY 2012 TOF and VTX construction; Muon trigger + “Small” upgrades: HBD, FMS, DAQ STAR HFT & PHENIX FVTX Next Generation Detector Upgrades STAR Forward/Inner Tracker System PHENIX Inner Tracker and Nosecone Cal Other approaches? RHIC Accelerator & Detector R&D LHC Heavy Ion Program Detector Upgrades Timeline EBIS construction RHIC II: construction operation Strawman schedule: depends on funding (TBD)* *Target for presenting a plan to DOE: January 2006
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Brookhaven Science Associates Quark Matter 2005, Budapest 14 RHIC vs. LHC LHC is not a replacement for RHIC - they complement each other ► Collision Energy RHIC probes high energy density at y~0. The initial state (CGC) is probed at forward rapidity (low x) LHC’s higher energies make high p T jets and heavy quarks more accessible. CGC is accessible at all rapidities ► Dedicated, flexible facility RHIC provides exploration vs. system size and energy, in hot and cold nuclear matter + p-p in the same detector. EBIS will expand the A-range and extend to U At RHIC QCD is the prime objective ► Unique capabilities with a future Unique spin program aimed at some of the biggest hadron physics problems. There is a path forward leading to a polarized DIS collider facility (eRHIC) ► Issues for the US in the LHC era The US program has great momentum and excellent teams to do the physics and train the next generation Just beginning to reap the benefits of a massive investment (people & equipment) The US RHI community will also work at LHC LHC is not a replacement for RHIC - they complement each other ► Collision Energy RHIC probes high energy density at y~0. The initial state (CGC) is probed at forward rapidity (low x) LHC’s higher energies make high p T jets and heavy quarks more accessible. CGC is accessible at all rapidities ► Dedicated, flexible facility RHIC provides exploration vs. system size and energy, in hot and cold nuclear matter + p-p in the same detector. EBIS will expand the A-range and extend to U At RHIC QCD is the prime objective ► Unique capabilities with a future Unique spin program aimed at some of the biggest hadron physics problems. There is a path forward leading to a polarized DIS collider facility (eRHIC) ► Issues for the US in the LHC era The US program has great momentum and excellent teams to do the physics and train the next generation Just beginning to reap the benefits of a massive investment (people & equipment) The US RHI community will also work at LHC &&
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Brookhaven Science Associates Quark Matter 2005, Budapest 15 Long term: 2013-2020 ► eRHIC Added e+A and polarized e+p capabilities New detector, augmented user community A+A, p+A, polarized p+p still available Construction possible 2012-2014 ► eRHIC Added e+A and polarized e+p capabilities New detector, augmented user community A+A, p+A, polarized p+p still available Construction possible 2012-2014
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Brookhaven Science Associates Quark Matter 2005, Budapest 16 Scientific Frontiers for eRHIC ► Partonic matter under extreme conditions Large “A” at RHIC : very high gluon densities Saturation/Color Glass Condensate ► Role of partons in nuclei Confinement in nuclei Hadronization in nuclear media ► Nucleon structure and spin Role of quarks & gluons in nucleons Issues of confinement, low-x & DVCS… ► Partonic matter under extreme conditions Large “A” at RHIC : very high gluon densities Saturation/Color Glass Condensate ► Role of partons in nuclei Confinement in nuclei Hadronization in nuclear media ► Nucleon structure and spin Role of quarks & gluons in nucleons Issues of confinement, low-x & DVCS…
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Brookhaven Science Associates Quark Matter 2005, Budapest 17 eRHIC at BNL High energy, high intensity polarized e (and e + ) beams to collide with existing heavy ion and polarized proton beams + A new detector for e-p & e-A physics = Precision tool to probe fundamental and universal aspects of QCD High energy, high intensity polarized e (and e + ) beams to collide with existing heavy ion and polarized proton beams + A new detector for e-p & e-A physics = Precision tool to probe fundamental and universal aspects of QCD E e = 10 GeV (~5-10 GeV) TO BE BUILT E p = 250 GeV (~50-250 GeV) EXISTS E A = 100 GeV/A (~ 10-100 GeV/A) EXISTS E e = 10 GeV (~5-10 GeV) TO BE BUILT E p = 250 GeV (~50-250 GeV) EXISTS E A = 100 GeV/A (~ 10-100 GeV/A) EXISTS
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Brookhaven Science Associates Quark Matter 2005, Budapest 18 eRHIC & Other DIS Facilities ► First polarized DIS collider – new kinematic region ► Variable energy, high luminosity: L ep ~10 33-34 cm -2 sec -1 ► Polarization of e,p and light ion beams ~ 70% ► Ion species from p to U high gluon densities TESLA-N eRHIC Jlab12GeV
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Brookhaven Science Associates Quark Matter 2005, Budapest 19 eRHIC design concepts simpler IR design multiple IRs possible E e ~ 20 GeV possible more expensive simpler IR design multiple IRs possible E e ~ 20 GeV possible more expensive Standard ring-ring designAlternative linac-ring design Schematic HERA-III type detector concept
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Brookhaven Science Associates Quark Matter 2005, Budapest 20 RHIC priorities and challenges ► e-cooling – enabling technology for the RHIC luminosity upgrade and for eRHIC R&D getting funding from a variety of sources New opportunities to make it cheaper and simpler ► Some major hurdles for QCD Lab Convince the community and NSAC LRP of science Establish priority relative to other future NP facilities Funding – construction & operating are not cheap ► Great opportunity, but will require a lot of work on many fronts ► e-cooling – enabling technology for the RHIC luminosity upgrade and for eRHIC R&D getting funding from a variety of sources New opportunities to make it cheaper and simpler ► Some major hurdles for QCD Lab Convince the community and NSAC LRP of science Establish priority relative to other future NP facilities Funding – construction & operating are not cheap ► Great opportunity, but will require a lot of work on many fronts
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Brookhaven Science Associates Quark Matter 2005, Budapest 21 QCD Lab A. Drees, A. Deshpande
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