The Heavy Flavor Tracker (HFT) An Update Spiros Margetis Kent State University, USA STAR Collaboration meeting, 2010 Nov 14, BNL.

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Presentation transcript:

The Heavy Flavor Tracker (HFT) An Update Spiros Margetis Kent State University, USA STAR Collaboration meeting, 2010 Nov 14, BNL

Outline A brief status of the project -> see Flemming’s talk HFT design/capabilities The key measurements of HFT Summary

HFT Status November 2009 – CD1 review with CDR Q&A responses completed in Spring 2010 August 2010 – CD1 granted Monthly project reporting started February/March 2011 – CD2/3 (TDR) Projected installation in Summer 2013 for Run-14

STAR Physics Program 1)At 200 GeV top energy - Study medium properties, EoS - pQCD in hot and dense medium 2) RHIC beam energy scan - Search for the QCD critical point - Chiral symmetry restoration Spin program - Study proton intrinsic properties Forward program - Study low-x properties, search for CGC - Study elastic (inelastic) processes (pp2pp) - Investigate gluonic exchanges

STAR DetectorMRPC ToF barrel 100% ready for run 10 (now!) BBC PMD FPD FMSFMS EMC barrel EMC End Cap DAQ1000 FGT Completed Ongoing MTD R&D HFT TPC FHC HLT

Heavy Quark Energy Loss Surprising results - - challenge our understanding of the energy loss mechanism - force us to RE-think about the elastic-collisions energy loss, etc - Requires direct measurements of c- and b-hadrons. 1) Non-photonic electrons decayed from - charm and beauty hadrons 2) At p T ≥ 6 GeV/c, R AA (n.p.e.) ~ R AA (h ± )! Contradicts naïve pQCD predictions STAR: Phys. Rew. Lett, 98, (2007).

Decay e p T vs. B- and C-hadron p T Key: Directly reconstructed heavy quark hadrons! Pythia calculation Xin Dong, USTC October 2005

The Bottom Line The HFT is meant to do full reconstruction of charm (and maybe bottom with MTD) decays, including low p T region. –PHENIX cannot but…it will do much by 2014 Main physics thrust besides surprises is: –Precise flow and R CP, R AA of identified charm –Extend the above to bottom through subtraction (or maybe identification)  C /D 0 ratio + individual particle spectroscopy + charm correlations + …

Challenge: e.g. D 0 decay length D 0 ->K+pi Decay Length in X-Y plane ~1 c  cm counts Used ~1GeV 1 GeV/  =0 D 0 has  Un-boost in Collider ! Mean R-  value ~ 80  m

HFT Strategy Replace Drift Silicon with small/square Pixels Move as close to beam as possible New beam pipe (Radius 4cm -> 2cm ) Keep it as thin as possible Si (300->50 microns) Air-cool Aluminum cable traces instead of Cu ~0.4% X 0 thickness per layer Remove/install with ~20 micron overall envelope Need special engineering

SSD SVT SSD+ IST PIXELS 23cm 15cm 11cm ~6.5cm 22cm 14cm 8cm 2.5cm Detector resolutions differ by a factor of 2-3 but pointing by a factor of ten. OLD (SVT)NEW (HFT).. SVT:~1.5%X0/layer PXL: %X0/layer

SSD+ R=22cm IST R=14cm Pixel 1-2 R=2.5, 8cm SSD+ IST PIXEL HFT Technology New beam pipe Low mass Near the event vertex Active pixels

SVT+SSD 10 Projection error is a strong function of first-layer distance and thickness

HFT

Heavy Quark Production NLO pQCD predictions of charm and bottom for the total p+p hadro-production cross sections. Renormalization scale and factorization scale were chosen to be equal. RHIC: 200, 500 GeV LHC: 900, GeV Ideal energy range for studying pQCD predictions for heavy quark production. Necessary reference for both, heavy ion and spin programs at RHIC. Estimated error bars of measurement comparable to line thickness! RHIC LHC R. Vogt

HFT Performance example on the D 0 ➝ Kπ reconstruction Simulation of Hijing events with STAR tracking software including pixel pileup (RHIC-II luminosity) extrapolated to 500 M events (~one RHIC run). Identification done via topological cuts and PID using Time Of Flight

In these plots, I required PixelHits =2 for all the 3 daughters The signal (height of the peak) is reduced but the background line too) No cuts L/  L >6 && pixHits=2 D + -> K  KALMAN fit

Ds ->  -> KK  PRELIMINARY Work in progress 1.gDCA > 80 um for daughters 2.nSigma_DV < 2 for daughters (the same nSigma_DV as Jan's) 3.cos(theta) > Phi inv mass within 3 Sigma of Phi mass

 c -> K p  P T spectra of  c NEW

HFT - Charm Hadron v GeV Au+Au minimum bias collisions (500M events). - Charm collectivity  drag/diffusion constants  medium properties! Charm-quark flow  Thermalization of light-quarks! Charm-quark does not flow  Drag coefficients

HFT - Charm Hadron R CP - Significant Bottom contributions in HQ decay electrons GeV Au+Au minimum bias collisions (|y|< M events). - Charm R AA  energy loss mechanism! D 0 s, NOT decay electrons

Λ C Measurements Λ C (  p + K + π): 1)Lowest mass charm baryon 2)Total yield and Λ C /D 0 ratios can be measured.

Strategies for Bottom Measurement (1.a) Displaced vertex electrons (TOF+HFT) (1) All Charm states ( D 0,±, D s,  C ) (2) Charm decay electrons (Charm) (1.a) - (2) Bottom decay electrons  Some Bottom states (Statistics limited at RHIC) Measure Charm and Bottom hadron: Cross sections, Spectra and v 2    With the MTD in place we currently explore semi-direct B-reconstruction via the J/Psi->dimuon channel (trigger)

B-meson capabilities (in progress) B->e+X approach Rate limited, not resolution

c- and b-decay Electrons - DCA cuts  c- and b-decay electron distributions and R CP GeV Au+Au minimum biased collisions (|y|< M events) H. van Hees et al. Eur. Phys. J. C61, 799(2009). (arXiv: )

Summary Detailed spectra of heavy flavor (c, b) is an invaluable piece of information provided by the HFT First generation of detectors needed smart replacements. The Heavy Flavor Tracker in STAR is the most advanced answer to this need …

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Low p T (≤ 2 GeV/c): hydrodynamic mass ordering High p T (> 2 GeV/c): number of quarks ordering s-quark hadron: smaller interaction strength in hadronic medium light- and s-quark hadrons: similar v 2 pattern => Collectivity developed at partonic stage! Partonic Collectivity at RHIC STAR: QM2009 STAR: preliminary

The di-Lepton Program at STAR TOF + TPC + HFT (1) σ (2) v 2 (3) R AA Mass (GeV/c 2 ) p T (GeV/c) ρ ϕ J/ψ DY, charm Bk Direct radiation from the Hot/Dense Medium Chiral symmetry Restoration  A robust di- lepton physics program extending STAR scientific reach PHENIX:

Quark Masses - Higgs mass: electro-weak symmetry breaking (current quark mass). - QCD mass: Chiral symmetry breaking (constituent quark mass). éStrong interactions do not affect heavy-quark mass. éNew scale compare to the excitation of the system. éStudy properties of the hot and dense medium at the foremost early stage of heavy-ion collisions. éExplore pQCD at RHIC. Total quark mass (MeV) X. Zhu, et al, Phys. Lett. B647, 366(2007).

MeasurementsRequirements Heavy Ion heavy-quark hadron v 2 - the heavy-quark collectivity - Low material budget for high reconstruction efficiency - p T coverage ≥ 0.5 GeV/c - mid-rapidity - High counting rate heavy-quark hadron R AA - the heavy-quark energy loss - High p T coverage ~ 10 GeV/c p+p energy and spin dependence of the heavy-quark production - p T coverage ≥ 0.5 GeV/c gluon distribution with heavy quarks - wide rapidity and p T coverage Requirement for the HFT

 -meson Flow: Partonic Flow “  -mesons (and other hadrons) are produced via coalescence of seemingly thermalized quarks in central Au+Au collisions. This observation implies hot and dense matter with partonic collectivity has been formed at RHIC” In order to test early thermalization: v 2 (p T ) of c- and b-hadrons data are needed! STAR: Phys. Rev. Lett. 99, (2007).

Charm Cross Sections at RHIC 1)Large systematic uncertainties in the measurements 2)New displaced, topologically reconstructed measurements for c- and b-hadrons are needed  Upgrade

SVT+SSD D0-vertex resolution (simulation) Left : correlation between reconstructed path length and MC Right : Decay length resolution –There is no systematic shift (red crosses = mean) in reconstructed quantities. –The standard deviation (blue crosses) of the distribution (reco-MC) is flat at ~ 250  m, which is of the order of the resolution of (SSD+SVT). Reco - MC [cm] MC [cm] Reco vs. MC [cm]

Glimpses at 200 GeV DATA TPC only Cu+Cu TPC+SVT+SSD Au+Au (Relatively) low significance peaks have been observed already in the DATA but of limited physics reach STAR preliminary

Charm Baryon/Meson Ratios Y. Oh, C.M. Ko, S.H. Lee, S. Yasui, Phys. Rev. C79, (2009). S.H. Lee, K.Ohnishi, S. Yasui, I-K.Yoo, C.M. Ko, Phys. Rev. Lett. 100, (2008). QGP medium  C  pK -  + D 0  K -  -+ 2-body collisions by c and ud 3-body collisions by c, u and d

Λ C Measurements Λ C (  p + K + π): 1)Lowest mass charm baryon 2)Total yield and Λ C /D 0 ratios can be measured.

The Bottom Line Hot and dense (partonic) matter with strong collectivity has been formed in Au+Au collisions at RHIC. Study of the properties of the new form of matter requires more penetrating probes like heavy quarks. Mechanism for parton energy loss. Thermalization. New micro-vertex detector is needed for STAR experiment. DOE milestone 2016: “Measure production rates, high pT spectra, and correlations in heavy-ion collisions at √s NN = 200 GeV for identified hadrons with heavy flavor valence quarks to constrain the mechanism for parton energy loss in the quark-gluon plasma.”

nuclei hadron gas CSC quark-gluon plasma TETE Baryon Chemical Potential Critical Point? Temperature Early Universe T E RHIC, FAIR 1 T ini, T C LHC, RHIC 3 Phase boundary RHIC, FAIR, NICA The QCD Phase Diagram and High-Energy Nuclear Collisions The nature of thermalization at the top energy:  Heavy quarks  Di-lepton The nature of thermalization at the top energy:  Heavy quarks  Di-lepton

Partonic Energy Loss at RHIC Central Au+Au collisions: light quark hadrons and the away-side jet in back-to- back ‘jets’ are suppressed. Different for p+p and d+Au collisions. Energy density at RHIC:  > 5 GeV/fm 3 ~ 30  0 Explore pQCD in hot/dense medium R AA (c,b) measurements are needed! STAR: Nucl. Phys. A757, 102(2005).

Ds ->  -> KK  42 PRELIMINARY NEW OLD work in progress