Directed flow of identified particles from Au+Au Collisions at RHIC
Resonance Production in RHIC Collisions
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Christina Markert Hot Quarks, Sardinia, Mai 2006 1 Christina Markert Kent State University • Motivation • Resonance in hadronic phase Time R AA and R dAu Elliptic flow v 2 • Summary for the STAR Collaboration Resonance Production in RHIC Collisions
description
Resonance Production in RHIC Collisions. Christina Markert Kent State University. for the STAR Collaboration. Motivation Resonance in hadronic phase Time R AA and R dAu Elliptic flow v 2 Summary. T chemical. T chemical. - PowerPoint PPT Presentation
Transcript of Resonance Production in RHIC Collisions
Christina Markert Hot Quarks, Sardinia, Mai 2006 1
Christina Markert Kent State University
• Motivation• Resonance in hadronic phase Time RAA and RdAu Elliptic flow v2• Summary
for the STAR Collaboration
Resonance Production in RHIC Collisions
Christina Markert Hot Quarks, Sardinia, Mai 2006 2
Lifetime of Nuclear Medium
TchemicalTchemical
t > 4 fm/cresonances
Au+Aut ~ 10 fm/c(HBT) Partonic phase < 6 fm/c
C. Markert, G. Torrieri, J. Rafelski, hep-ph/0206260 + STAR delta lifetime > 4fm/c
Christina Markert Hot Quarks, Sardinia, Mai 2006 3
Hot
and
den
se
med
ium
p+p
Au+AuAu+Au interactions:• Extended hot and dense phase• Thermalization at chem. freeze-out• Kinetic freeze-out separated from chemical freeze-out
p+p interactions:• No extended initial medium• Chemical freeze-out (no thermalization)• Kinetic freeze-out close to the chemical freeze-out
Particle yields Particle spectra
time
p
K
p
K
Time in Heavy Ion Reactions
Christina Markert Hot Quarks, Sardinia, Mai 2006 4
Resonance Signals in p+p and Au+Au collisions from STAR
K(892)
(1520)
p+p
p+p
Au+Au
Au+Au (1385)
p+pAu+Au
(1020) p+p
Au+Au
p+p
K(892) K+
(1232) p+ (1020) K + K(1520) p + K(1385) +
Christina Markert Hot Quarks, Sardinia, Mai 2006 5
* and* show rescattering * shows regenerationRegeneration/Rescattering cross section:p)
Interactions of Resonance in Hadronic Nuclear Medium
[1] P. Braun-Munzinger et.al.,PLB 518(2001) 41, priv. communication[2] Marcus Bleicher and Jörg Aichelin Phys. Lett. B530 (2002) 81. M. Bleicher and Horst Stöcker J. Phys.G30 (2004) 111.
Life-time [fm/c] :
Preliminary
UrQMD =10±3 fm/c
Christina Markert Hot Quarks, Sardinia, Mai 2006 6
+X Y
+X Y
+X Y
Regeneration Cross Sections
Regeneration/Rescattering cross section:
Sascha Vogel, San Diego Winter Workshop 2006
Production channel for measured resonances:UrQMD calculations
Christina Markert Hot Quarks, Sardinia, Mai 2006 7
RAA of Resonances (with rescattering)
• K(892) more suppressed in AA than Ks0
• K(892) are lower than Ks0 (and )
pt < 2.0 GeV factor of 2
Christina Markert Hot Quarks, Sardinia, Mai 2006 8
Nuclear Modification Factor RdAu
1. K* is lower than Kaons in low pt d+Au no medium no rescattering why K* suppression in d+Au ?
* follows h+- and lower than protons .
Christina Markert Hot Quarks, Sardinia, Mai 2006 9
Medium in d+Au ?
Preliminary
*: No rescattering in hadronic d+Au mediumK* : Rescattering in hadronic d+Au medium
???
Christina Markert Hot Quarks, Sardinia, Mai 2006 10
Low mean pT ≠ early freeze-out ?
Resonance are regenerating close to kinetic freeze-out we measure late produced (1385)How is elliptic flow v2 effected ?v2= signal for early partonic interactions
Fit to and Higher T kin and lower <T>
Christina Markert Hot Quarks, Sardinia, Mai 2006 11
Effects on v2 of and from Resonances
v2 of pions:1. Primary produced (30%)2. Early resonance decay3. Late resonance decay
v2 of resonances:1. Early resonances2. Regenerated resonances
time
chem
ical
free
ze-
out
p
pp
kine
tic fr
eeze
-out
re-scattering
regeneration
Christina Markert Hot Quarks, Sardinia, Mai 2006 12
Resonances v2 and NCQ Scaling TestEl
lipti
c flo
w v
2
pT (GeV) Fluid dynamics calculations (zero viscosity) describe data pT < 2 GeV Do Resonances show same mass splitting ? Number of Constituent Quark (NCQ) scaling at intermediate pT (2= mesons, 3= baryons) indication of partonic degrees of freedomRegenerated resonances–final state interactions NCQ = 5 (* = + =3+2)
C. Nonaka, et al.,Phys.Rev.C69:031902,2004
Christina Markert Hot Quarks, Sardinia, Mai 2006 13
elliptic flow v2 in minbias Au+Au 200 GeV
2(-)
2( -)
dN
/d(
-)
dN/
d(-
)
signal
Bg of invmass
v2=12±2%
v2=16±0.04%
pT = 1.0-1.5 GeV
Inv mass (K+ K-)
Inv mass (K+ K-)
Elliptic flow
)](2cos[21 2 RvddN
Reaction plane
Kaon p < 0.6 GeV
Christina Markert Hot Quarks, Sardinia, Mai 2006 14
v2 of phi resonance in Au+Au 200GeV
has long lifetime 45fm/c less rescattering or regenerationElliptic flow of Φ-meson is close to Ks Delta resonance ?
STAR PreliminarySTAR Preliminary
Christina Markert Hot Quarks, Sardinia, Mai 2006 15
Summary
• Hadronic resonances help to separate hadronic from partonic lifetime
• Ranking of rescattering over regeneration cross section in medium.
•Low pt RAA behavior confirms rescattering hypothesis. (RdAu puzzle?)
• v2 of long lived resonances seems to follow stable particle trends (confirmation of NCQ scaling)
Christina Markert Hot Quarks, Sardinia, Mai 2006 16
For Raymond
Christina Markert Hot Quarks, Sardinia, Mai 2006 17
Signal Loss in Low pT Region
Inverse slope increase from p+p to Au+Au collisions. UrQMD predicts signal loss at low pT due to rescattering of decay daughters. Inverse slopes T and mean pT are higher.Flow would increase pT of higher masse particles stronger.
pT UrQMD 140 MeV 90 MeV 35 MeV
p+p
Au+Au
K(892)
flowpT
Preliminary
Christina Markert Hot Quarks, Sardinia, Mai 2006 18
Temperature and “Life-time” fromK* and *
Model includes: • Temperature at chemical freeze-out• “Life-time” between chemical and thermal freeze-out• By comparing two particle ratios (no regeneration)
Lambda1520 T= 160 MeV > 4 fm/c K(892) T = 160 MeV > 1.5 fm/c
(1520)/ = 0.039 0.015 at 10% most central Au+Au
K*/K- = 0.23 0.05 at 0-10% most central Au+Au
G. Torrieri and J. Rafelski, Phys. Lett. B509 (2001) 239
Life time:K(892) = 4 fm/c (1520) = 13 fm/c
