TQFT 2010 T. Umeda (Hiroshima) 1
Equation of State in 2+1 flavor Equation of State in 2+1 flavor QCD QCD with improved Wilson with improved Wilson quarksquarks
Takashi Umeda (Hiroshima Univ.)Takashi Umeda (Hiroshima Univ.)
for WHOT-QCD Collaborationfor WHOT-QCD Collaboration
TQFT 2010, YITP, Kyoto, 30 Aug. 2010TQFT 2010, YITP, Kyoto, 30 Aug. 2010
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TQFT 2010 2
Quark Gluon Plasma in Lattice QCD
from the Phenix group web-site
Observables in Lattice QCDObservables in Lattice QCD
Phase diagram in (T, Phase diagram in (T, μμ, m, mudud, m, mss))
Transition temperatureTransition temperature
Equation of state ( ε/TEquation of state ( ε/T44, p/T, p/T44,...),...)
Hadronic excitationsHadronic excitations
Transport coefficientsTransport coefficients
Finite chemical potentialFinite chemical potential
etc...etc...http://www.gsi.de/fair/experiments/
T. Umeda (Hiroshima) /15
TQFT 2010 T. Umeda (Hiroshima) 3
Choice of quark actions on the lattice
Most (T, μ≠0) studies done with staggerd-type quarksMost (T, μ≠0) studies done with staggerd-type quarks less computational costsless computational costs a part of chiral sym. preserved ...a part of chiral sym. preserved ...
NNff=2+1, almost physical quark mass, (μ≠0)=2+1, almost physical quark mass, (μ≠0)
4th-root trick to remove unphysical “tastes”4th-root trick to remove unphysical “tastes”
non-locality “universality is not guaranteed”non-locality “universality is not guaranteed”
It is important to cross-check with It is important to cross-check with
theoretically sound lattice quarks like Wilson-type quarkstheoretically sound lattice quarks like Wilson-type quarks
Our aim is to investigateOur aim is to investigate
QCD Thermodynamics with Wilson-type quarksQCD Thermodynamics with Wilson-type quarks
WHOT-QCD CollaborationWHOT-QCD Collaboration
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TQFT 2010 T. Umeda (Hiroshima) 4
Fixed scale approach to study QCD thermodynamics
Temperature Temperature T=1/(NT=1/(Ntta)a) is varied by is varied by NNtt at fixed at fixed aa
AdvantagesAdvantages
- Line of Constant Physics- Line of Constant Physics
- T=0 subtraction for renorm.- T=0 subtraction for renorm.
(spectrum study at T=0 )(spectrum study at T=0 )
- larger 1/a in whole T region- larger 1/a in whole T region
DisadvantagesDisadvantages
- T resolution by integer N- T resolution by integer Ntt
- coding for odd N- coding for odd Ntt
- Integration method- Integration method
is not applicableis not applicable
a : lattice spacinga : lattice spacingNNtt : lattice size in temporal direction : lattice size in temporal direction
Temperatures in each approachTemperatures in each approach
fixed Nfixed N tt a
pproach approach
fixed scale approachfixed scale approach
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TQFT 2010 T. Umeda (Hiroshima) 5
T-integration method to calculate the EOS
We propose a new method (“We propose a new method (“T-integration methodT-integration method”) ”)
to calculate the EOS at fixed scalesto calculate the EOS at fixed scales
Our method is based on Our method is based on the trace anomaly (interaction measure),the trace anomaly (interaction measure),
and and the thermodynamic relation.the thermodynamic relation.
T.Umeda et al. (WHOT-QCD), Phys.Rev.D79 (2009) 051501(R)T.Umeda et al. (WHOT-QCD), Phys.Rev.D79 (2009) 051501(R)
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TQFT 2010 T. Umeda (Hiroshima) 6
Test in quenched QCD
Our results are roughlyOur results are roughly consistent with previous results. consistent with previous results.
Our results deviate from the Our results deviate from the fixed Nfixed Ntt=8 results [*] =8 results [*] at higher T ( aT~0.3 or higher )at higher T ( aT~0.3 or higher )
Trace anomaly is sensitive toTrace anomaly is sensitive to spatial volume at lower Tspatial volume at lower T (below T(below Tcc).). V > (2fm)V > (2fm)33 is ncessarry. is ncessarry.
~~
[*] [*] G. Boyd et al., NPB469, 419 (1996) G. Boyd et al., NPB469, 419 (1996)
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TQFT 2010 T. Umeda (Hiroshima) 7
T=0 & T>0 configurations for Nf=2+1 QCD
T=0 simulation: on 28T=0 simulation: on 2833 x 56 x 56 by CP-PACS/JLQCDby CP-PACS/JLQCD Phys. Rev. D78 (2008) 011502Phys. Rev. D78 (2008) 011502
- - RG-improved Iwasaki glue + NP-improved Wilson quarksRG-improved Iwasaki glue + NP-improved Wilson quarks
- β=2.05, κ- β=2.05, κudud=0.1356, κ=0.1356, κss=0.1351=0.1351
- V~(2 fm)- V~(2 fm)33 , a=0.07 fm, , a=0.07 fm,
- configurations available on the - configurations available on the ILDG/JLDGILDG/JLDG
T>0 simulations: on 32T>0 simulations: on 3233 x N x Ntt (N (Ntt=4, 6, ..., 14, 16) lattices=4, 6, ..., 14, 16) lattices
RHMC algorithm, same parameters as T=0 simulationRHMC algorithm, same parameters as T=0 simulation
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TQFT 2010 T. Umeda (Hiroshima) 8
Formulation for Nf=2+1 improved Wilson quarks
Noise methodNoise method ( #noise = 1 for each color & spin indices ) ( #noise = 1 for each color & spin indices )
Phys. Rev. D73, 034501Phys. Rev. D73, 034501CP-PACS/JLQCDCP-PACS/JLQCD
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TQFT 2010 T. Umeda (Hiroshima) 9
Beta-functions from CP-PACS/JLQCD results
Trace anomaly needsTrace anomaly needs Beta-functions Beta-functions in N in Nff=2+1 QCD=2+1 QCD
Direct fit method Direct fit method Phys. Rev. D64 (2001) 074510Phys. Rev. D64 (2001) 074510
fit fit ββ,,κκudud,,κκss as functions of as functions of
with fixed with fixed
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TQFT 2010 T. Umeda (Hiroshima) 10
Beta-functions from CP-PACS/JLQCD results
χχ22/dof=5.3/dof=5.3χχ22/dof=1.6/dof=1.6 χχ22/dof=2.1/dof=2.1
Meson spectrum by CP-PACS/JLQCD Meson spectrum by CP-PACS/JLQCD Phys. Rev. D78 (2008) 011502Phys. Rev. D78 (2008) 011502. .
fit fit ββ,,κκudud,,κκss as functions of as functions of
3 (β) x 5 (κ3 (β) x 5 (κudud) x 2 (κ) x 2 (κss) = 30 data points) = 30 data points
only statistical erroronly statistical error
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TQFT 2010 T. Umeda (Hiroshima) 11
Trace anomaly in Nf=2+1 QCD
Nt config. (x 5MD traj.)Nt config. (x 5MD traj.) SSgg S Sq q
(**)(**)
56 56 13001300(*)(*) 980 980 16 1542 64716 1542 647 14 1448 647 14 1448 647 12 1492 69512 1492 695 10 863 48710 863 487 8 628 5208 628 520 6 657 3606 657 360 4 802 2954 802 295
(*) T=0 (Nt=56) by CP-PACS/JLQCD(*) T=0 (Nt=56) by CP-PACS/JLQCD SSgg calculated with 6500traj. calculated with 6500traj.(**) thermal. = 1000 traj.(**) thermal. = 1000 traj.
Preliminary Preliminary
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TQFT 2010 T. Umeda (Hiroshima) 12
Trace anomaly in Nf=2+1 QCD
HotQCD PRD80,014504(2009)HotQCD PRD80,014504(2009)
Aoki et al. JHEP01,089(2006)Aoki et al. JHEP01,089(2006) HotQCD arXiv1005.1131HotQCD arXiv1005.1131
p4p4
HISQHISQ
stoutstout
asqtadasqtad
peak height ~ 5-8peak height ~ 5-8 in Staggered resultsin Staggered results ( m( mq q ~ m~ mqq
phys. phys. ))
Preliminary Preliminary
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TQFT 2010 T. Umeda (Hiroshima) 13
Quark mass dependence of Trace anomaly
HotQCD arXiv1005.1131HotQCD arXiv1005.1131
0.05m0.05mss
0.2m0.2mss
HotQCD PRD91,054504(2010)HotQCD PRD91,054504(2010) CP-PACS CP-PACS PRD64,074510 (2001)PRD64,074510 (2001)
peak height of the Trace anomalypeak height of the Trace anomaly small quark mass dependencesmall quark mass dependence
Our result seems to be reasonable !Our result seems to be reasonable ! but small mbut small mqq is necessary. is necessary.
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TQFT 2010 T. Umeda (Hiroshima) 14
Equation of State in Nf=2+1 QCD
PreliminaryPreliminary T-integrationT-integration
is performed by the trapezoidal is performed by the trapezoidal rule (straight line interpolation). rule (straight line interpolation).
ε/Tε/T44 is calculated from is calculated from
Large error in whole T regionLarge error in whole T region
SB limitSB limit
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TQFT 2010 T. Umeda (Hiroshima) 15
Summary & outlook
Equation of stateEquation of state
More statistics More statistics are needed in the lower temperature region are needed in the lower temperature region
Results at different scales (β=1.90 by CP-PACS/JLQCD)Results at different scales (β=1.90 by CP-PACS/JLQCD)
NNff=2+1 QCD just at the physical point=2+1 QCD just at the physical point
the physical point (pion mass ~ 140MeV) by PACS-CSthe physical point (pion mass ~ 140MeV) by PACS-CS
Finite densityFinite density
We can combine our approach with the Taylor expansion method,We can combine our approach with the Taylor expansion method,
to explore EOS at to explore EOS at μμ≠≠00
We presented the EOS in NWe presented the EOS in Nff=2+1 QCD using improve Wilson quarks=2+1 QCD using improve Wilson quarks
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