Thermal phase transition of color superconductivity with Ginzburg-Landau effective action on the lattice M. Ohtani ( RIKEN ) with S. Digal (Univ. of Tokyo)

Slides:

Advertisements

Similar presentations

A method of finding the critical point in finite density QCD

Advertisements

A). Introduction b). Quenched calculations c). Calculations with 2 light dynamical quarks d). (2+1) QCD LATTICE QCD SIMULATIONS, SOME RECENT RESULTS (END.

R. Yoshiike Collaborator: K. Nishiyama, T. Tatsumi (Kyoto University)

The QCD equation of state for two flavor QCD at non-zero chemical potential Shinji Ejiri (University of Tokyo) Collaborators: C. Allton, S. Hands (Swansea),

Lattice QCD (INTRODUCTION) DUBNA WINTER SCHOOL 1-2 FEBRUARY 2005.

23 Jun. 2010Kenji Morita, GSI / XQCD20101 Mass shift of charmonium near QCD phase transition and its implication to relativistic heavy ion collisions Kenji.

TQFT 2010T. Umeda (Hiroshima)1 Equation of State in 2+1 flavor QCD with improved Wilson quarks Takashi Umeda (Hiroshima Univ.) for WHOT-QCD Collaboration.

Masato Yamanaka (ICRR, University of Tokyo) Collaborators Junji Hisano, Kazunori Nakayama Shohei Sugiyama, Tomohiro Takesako.

QCD – from the vacuum to high temperature an analytical approach.

Naoki Yamamoto (Univ. of Tokyo) Tetsuo Hatsuda (Univ. of Tokyo) Motoi Tachibana (Saga Univ.) Gordon Baym (Univ. of Illinois) Phys. Rev. Lett. 97 (2006)

N F = 3 Critical Point from Canonical Ensemble χ QCD Collaboration: A. Li, A. Alexandru, KFL, and X.F. Meng Finite Density Algorithm with Canonical Approach.

Kenji Morita 21 May 2011Three Days on Quarkyonic Poland1 Probing deconfinement in a chiral effective model with Polyakov loop from imaginary.

Introduction to Gauge Higgs unification with a graded Lie algebra Academia Sinica, Taiwan Jubin Park (NTHU)  Collaboration with Prof. We-Fu.

Color confinement mechanism and the type of the QCD vacuum Tsuneo Suzuki (Kanazawa Univ.) Collaborators: K.Ishiguro, Y.Mori, Y.Nakamura, T.Sekido （ M.Polikarpov,

1 Debye screened QGP QCD : confined Chiral Condensate Quark Potential Deconfinement and Chiral Symmetry restoration expected within QCD mm symmetryChiral.

1 Heavy quark Potentials in Full QCD Lattice Simulations at Finite Temperature Yuu Maezawa (The Univ. of Tokyo) Tsukuba-Tokyo collaboration Univ. of Tsukuba.

1 Thermodynamics of two-flavor lattice QCD with an improved Wilson quark action at non-zero temperature and density Yu Maezawa (Univ. of Tokyo) In collaboration.

Discovery of the Higgs Boson Gavin Lawes Department of Physics and Astronomy.

Chiral symmetry breaking in dense QCD

Finite Density with Canonical Ensemble and the Sign Problem Finite Density Algorithm with Canonical Ensemble Approach Finite Density Algorithm with Canonical.

A direct relation between confinement and chiral symmetry breaking in temporally odd-number lattice QCD Lattice 2013 July 29, 2013, Mainz Takahiro Doi.

Introduction to Flavor Physics in and beyond the Standard Model

Thermodynamics and Z(N) interfaces in large N matrix model RIKEN BNL Shu Lin SL, R. Pisarski and V. Skokov, arXiv: arXiv: YITP, Kyoto.

Imaginary Chemical potential and Determination of QCD phase diagram

T BB Hadronic matter Quark-Gluon Plasma Chiral symmetry broken Chiral symmetry restored Early universe A new view and on the QCD phase diagram Recent.

Axel Drees, Stony Brook University, Lectures at Trento June 16-20, 2008 Electromagnetic Radiation form High Energy Heavy Ion Collisions I.Lecture:Study.

INVASIONS IN PARTICLE PHYSICS Compton Lectures Autumn 2001 Lecture 8 Dec

1 2+1 Flavor lattice QCD Simulation on K computer Y.Kuramashi U. of Tsukuba/RIKEN AICS August 2, Mainz.

Komaba seminarT.Umeda (Tsukuba)1 A study of charmonium dissociation temperatures using a finite volume technique in the lattice QCD T. Umeda and H. Ohno.

Molecular dynamics simulation of strongly coupled QCD plasmas Peter Hartmann 1 Molecular dynamics simulation of strongly coupled QCD plasmas Péter Hartmann.

Review of recent highlights in lattice calculations at finite temperature and finite density Péter Petreczky Symmetries of QCD at T>0 : chiral and deconfinement.

Thermal phase transitions in realistic dense quark matter

Color neutrality effects in the phase diagram of the PNJL model A. Gabriela Grunfeld Tandar Lab. – Buenos Aires - Argentina In collaboration with D. Blaschke.

Lattice2014T. Umeda (Hiroshima) Thermodynamics in the fixed scale approach with the shifted boundary conditions Takashi Umeda (Hiroshima Univ.) Lattice2014,

Why Extra Dimensions on the Lattice? Philippe de Forcrand ETH Zurich & CERN Extra Dimensions on the Lattice, Osaka, March 2013.

X ± -Gauge Boson Production in Simplest Higgs Matthew Bishara University of Rochester Meeting of Division of Particles and Fields August 11, 2011  Simplest.

Center-Symmetric 1/N Expansion Phys.Rev.D71, (hep-th/ v2) Outline : A center-symmetric background at finite temperature ‘t Hooft diagrams and.

WHOT-QCD Collaboration Yu Maezawa (RIKEN) in collaboration with S. Aoki, K. Kanaya, N. Ishii, N. Ukita, T. Umeda (Univ. of Tsukuba) T. Hatsuda (Univ. of.

The axial anomaly and the phases of dense QCD

Quark spectrum near chiral and color-superconducting phase transitions Masakiyo Kitazawa Kyoto Univ. M.K., T.Koide, T.Kunihiro and Y.Nemoto, PRD70,

QCD 相転移における秩序変数揺らぎとクォークスペクトル根本幸雄 ( 名古屋大 ) with 北沢正清 ( 基研 ) 国広悌二 ( 基研 ) 小出知威 (Rio de Janeiro Federal U.)

Lattice QCD at finite density

JPS spring 2012T. Umeda (Hiroshima)1 固定格子間隔での有限温度格子 QCD の研究 Takashi Umeda (Hiroshima Univ.) for WHOT-QCD Collaboration JPS meeting, Kwansei-gakuin, Hyogo,

1 Nontopological Soliton in the Polyakov Quark Meson Model Hong Mao ( 毛鸿 ) Department of Physics, Hangzhou Normal University With: Jinshuang Jin （ HZNU.

Monday, Apr. 7, 2003PHYS 5326, Spring 2003 Jae Yu 1 PHYS 5326 – Lecture #20 Monday, Apr. 7, 2003 Dr. Jae Yu Super Symmetry Breaking MSSM Higgs and Their.

1 Heavy quark potential in full QCD lattice simulations at finite temperature Yuu Maezawa (The Univ. of Tokyo) Tsukuba-Tokyo collaboration Univ. of Tsukuba.

K.M.Shahabasyan, M. K. Shahabasyan,D.M.Sedrakyan

Toru T. Takahashi with Teiji Kunihiro ・ Why N*(1535)? ・ Lattice QCD calculation ・ Result TexPoint fonts used in EMF. Read the TexPoint manual before you.

Quarks Quarks in the Quark-Gluon Plasma Masakiyo Kitazawa (Osaka Univ.) Tokyo Univ., Sep. 27, 2007 Lattice Study of F. Karsch and M.K., arXiv:

An Introduction to Lattice QCD and Monte Carlo Simulations Sinya Aoki Institute of Physics, University of Tsukuba 2005 Taipei Summer Institute on Particles.

Lecture 7. Tuesday… Superfield content of the MSSM Gauge group is that of SM: StrongWeakhypercharge Vector superfields of the MSSM.

June 4, Tokyo Anomalous Viscosity of an Expanding Quark-Gluon Plasma Masayuki ASAKAWA Department of Physics, Osaka University S. A. Bass,

Study of sigma meson structure in D meson decay Masayasu Harada (Nagoya Univ.) at International Workshop on New Hadon Spectroscopy (November 21, 2012,

Gauge independence of Abelian dual Meissner effect in pure SU(2) QCD Katsuya Ishiguro Y.Mori, T.Sekido, T.Suzuki Kanazawa-univ & RIKEN Joint Meeting of.

S. Aoki (Univ. of Tsukuba), T. Doi (Univ. of Tsukuba), T. Hatsuda (Univ. of Tokyo), T. Inoue (Univ. of Tsukuba), N. Ishii (Univ. of Tokyo), K. Murano (Univ.

高密度クォーク物質におけるカイラル凝縮とカラー超伝導の競合 M. Kitazawa,T. Koide,Y. Nemoto and T.K. Prog. of Theor. Phys., 108, 929(2002) 国広悌二 ( 京大基研）東大特別講義 2005 年 12 月 5-7 日 Ref.

1 NJL model at finite temperature and chemical potential in dimensional regularization T. Fujihara, T. Inagaki, D. Kimura : Hiroshima Univ.. Alexander.

Review of ALICE Experiments

-Nucleon Interaction and Nucleon Mass in Dense Baryonic Matter

Gauge/String Duality and Integrable Systems

Thermodynamics of QCD in lattice simulation with improved Wilson quark action at finite temperature and density WHOT-QCD Collaboration Yu Maezawa (Univ.

WHOT-QCD Collaboration Yu Maezawa (RIKEN) in collaboration with

Raju Venugopalan Brookhaven National Laboratory

Color Superconductivity in dense quark matter

Spontaneous P-parity breaking in QCD at large chemical potentials

Neutron EDM with external electric field

Teiji Kunihiro (Kyoto) In collaboration with

Hadron Multiplicity from Color Glass Condensate at LHC

QCD at very high density

EoS in 2+1 flavor QCD with improved Wilson fermion

Presentation transcript:

Thermal phase transition of color superconductivity with Ginzburg-Landau effective action on the lattice M. Ohtani ( RIKEN ) with S. Digal (Univ. of Tokyo) T. Hatsuda (Univ. of Tokyo) XQCD, Aug Swansea Introduction GL effective action Phase diagram in weak gauge coupling Phase transition on the lattice Summary

Δ ~ 100MeV T c ~ 60MeV Introduction Non-perturbative analysis of colorsuper transition Ｔ μ Hadrons Quark-Gluon Plasma Color Superconductivity RHIC 170MeV ~400MeV N ☆ Cores    qq   0

¶ no sign problem bosonic T-  dependence: m, i, ,  g (( Ginzburg-Landau effective action  GL action in terms of the quark pair field  fc (x) & gauge field  Iida & Baym PRD 65 (2002) { discretize & rescale SU f (3)  SU c (3) Higgs on Lattice 2 couplings for quartic terms ○○○

mean field without gluon  Iida & Baym PRD 63 (2001) mean field (ungauged) normal  CFL normal  2SC   unbound 2 nd order transition            as T c (MF) 1 = 2 in weak coupling

weak gauge coupling limit mean field (ungauged) perturbative analysis  Matsuura,Hatsuda,Iida,Baym PRD 69 (2004) Normal  CFL normal  2SC   unbound 2 nd order transition gluonic fluctuation |  | 3 term 1 st order transition normal  2SC   normal  2SC  CFL unbound normal  CFL

normal unbound Phase diagram in weak gauge coupling CFL 2SC  T/T c (MF)    

Phase diagram in weak gauge coupling

Analytic results for large  mean field (ungauged) perturbative analysis Normal  CFL normal  2SC   unbound 2 nd order transition gluonic fluctuation 1 st order transition normal  2SC   normal  2SC  CFL unbound normal  CFL

parameters Setup for Monte-Carlo simulation Lattice size L t = 2, L s = 12, 16, 24, 32, RIKEN Super Combined Cluster pseudo heat-bath method for gauge field generalized update-algorithm of SU(2) Higgs-field  = 5.1  0.7   c in pure YM  take several pairs of ( 1, 2 ), scanning  { with 3,000 － 60,000 configurations  Bunk, NP(Proc.Suppl) 42 (‘95), 556 update

broken phase  Phase identification (Tr  †  ) 1/2 large order param. ⇔ broken phase plateau  c update step phase transition to ‘color super’ Tr  x †  x ¶ Tr  x †  x  0 even in sym. phase thermal fluctuation 

identifying the phases by eigenvalues of  y  diagonalization matrix elements of  †   †    ・・・ CFL a  †   b ・・・ 2SC b ¶  †  :  gauge invariant

Hadron (Quark-Gluon Plasma) Color Superconducting state  Phase diagram with i fixed 3.6 CFL 2SC normal ● Similar trends with SU(2) Higgs ● no clear signal of end points as i 1 = 2 =.0005 

2SC CFL 1 st order transition: Hysteresis & boundary shift initial config. = a thermalized config. with slightly different   Hysteresis : different configs. with same   Put 3 configs in spatial sub-domain  Thermalize it with fixed  Polyakov loop normal  CFL 2SC

Phase diagram with  fixed 1 2 CFL 2SC 1 st order transition CFL w/ metastable 2SC 2SC  CFL lattice simulation metastable 2SC: 2SC observed in hysteresis & disappeared in boundary shift test perturbative analysis 2SC   2SC  CFL unbound CFL

Free energy by perturbation    =   normal CFL    †        2SC  Iida,Matsuura,Tachibana,Hatsuda PRD 71 (2005) ● largest barrier btw normal &CFL ●   metastable 2SC

Summary and outlook  GL approach with quark pair field  & gauge on lattice  SU(3) Higgs model  eigenvalues of  †  to identify the phases  1 st order trans. to CFL & 2SC phases in coupling space  We observed hysteresis. transition points  boundary shift with mixed domain config.   metastable 2SC state in transition from normal to CFL, which is consistent with perturbative analysis  charge neutrality, quark mass effects, correction to scaling, phase diagram in T -  …