Axial symmetry at finite temperature Guido Cossu High Energy Accelerator Research Organization – KEK Lattice Field Theory on multi-PFLOPS computers German-Japanese.

Slides:

Advertisements

Similar presentations

Lecture 1: basics of lattice QCD Peter Petreczky Lattice regularization and gauge symmetry : Wilson gauge action, fermion doubling Different fermion formulations.

Advertisements

P. Vranas, IBM Watson Research Lab 1 Gap domain wall fermions P. Vranas IBM Watson Research Lab.

1 Meson correlators of two-flavor QCD in the epsilon-regime Hidenori Fukaya (RIKEN) with S.Aoki, S.Hashimoto, T.Kaneko, H.Matsufuru, J.Noaki, K.Ogawa,

2+1 Flavor Polyakov-NJL Model at Finite Temperature and Nonzero Chemical Potential Wei-jie Fu, Zhao Zhang, Yu-xin Liu Peking University CCAST, March 23,

Scaling properties of the chiral phase transition in the low density region of two-flavor QCD with improved Wilson fermions WHOT-QCD Collaboration: S.

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

第十届 QCD 相变与相对论重离子物理研讨会, August Z. Zhang,

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

Su Houng Lee Theme: 1.Will U A (1) symmetry breaking effects remain at high T/  2.Relation between Quark condensate and the ’ mass Ref: SHL, T. Hatsuda,

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.

1 A Model Study on Meson Spectrum and Chiral Symmetry Transition Da

1 Chiral Symmetry Breaking and Restoration in QCD Da Huang Institute of Theoretical Physics, Chinese Academy of

O(N) linear and nonlinear sigma-model at nonzeroT within the auxiliary field method CJT study of the O(N) linear and nonlinear sigma-model at nonzeroT.

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

Towards θvacuum simulation in lattice QCD Hidenori Fukaya YITP, Kyoto Univ. Collaboration with S.Hashimoto (KEK), T.Hirohashi (Kyoto Univ.), K.Ogawa(Sokendai),

Phases of planar QCD1 July 26, Lattice 05, Dublin Phases of planar QCD on the torus H. Neuberger Rutgers On the two previous occasions that I gave plenary.

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

Excited Hadrons: Lattice results Christian B. Lang Inst. F. Physik – FB Theoretische Physik Universität Graz Oberwölz, September 2006 B ern G raz R egensburg.

Toward an Improved Determination of Tc with 2+1 Flavors of Asqtad Fermions C. DeTar University of Utah The HotQCD Collaboration July 30, 2007.

Chiral Magnetic Effect on the Lattice Komaba, June 13, 2012 Arata Yamamoto (RIKEN) AY, Phys. Rev. Lett. 107, (2011) AY, Phys. Rev. D 84,

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.

ATHIC2008T.Umeda (Tsukuba)1 QCD Thermodynamics at fixed lattice scale Takashi Umeda (Univ. of Tsukuba) for WHOT-QCD Collaboration ATHIC2008, Univ. of Tsukuba,

Guido Cossu 高エネルギ加速器研究機構 Lattice Hosotani mechanism on the lattice o Introduction o EW symmetry breaking mechanisms o Hosotani mechanism.

Dynamical Chirally Improved Quarks: First Results for Hadron MassesC.B. Lang : Dynamical Chirally Improved Quarks: First Results for Hadron Masses C. B.

In-medium hadrons and chiral symmetry G. Chanfray, IPN Lyon, IN2P3/CNRS, Université Lyon I The Physics of High Baryon Density IPHC Strasbourg, september.

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

TopologyT. Onogi1 Should we change the topology at all? Tetsuya Onogi (YITP, Kyoto Univ.) for JLQCD collaboration RBRC Workshp: “Domain Wall Fermions at.

1.Introduction 2.Formalism 3.Results 4.Summary I=2 pi-pi scattering length with dynamical overlap fermion I=2 pi-pi scattering length with dynamical overlap.

Exploring Real-time Functions on the Lattice with Inverse Propagator and Self-Energy Masakiyo Kitazawa (Osaka U.) 22/Sep./2011 Lunch BNL.

Lattice Fermion with Chiral Chemical Potential NTFL workshop, Feb. 17, 2012 Arata Yamamoto (University of Tokyo) AY, Phys. Rev. Lett. 107, (2011)

MEM analysis of the QCD sum rule and its Application to the Nucleon spectrum Tokyo Institute of Technology Keisuke Ohtani Collaborators : Philipp Gubler,

Topology conserving actions and the overlap Dirac operator (hep-lat/ ) Hidenori Fukaya Yukawa Institute, Kyoto Univ. Collaboration with S.Hashimoto.

Eigo Shintani (KEK) (JLQCD Collaboration) KEKPH0712, Dec. 12, 2007.

Condensates and topology fixing action Hidenori Fukaya YITP, Kyoto Univ. Collaboration with T.Onogi (YITP) hep-lat/

Instanton-induced contributions to hadronic form factors. Pietro Faccioli Universita’ degli Studi di Trento, I.N.F.N., Gruppo Collegato di Trento, E.C.T.*

1 Approaching the chiral limit in lattice QCD Hidenori Fukaya (RIKEN Wako) for JLQCD collaboration Ph.D. thesis [hep-lat/ ], JLQCD collaboration,Phys.Rev.D74:094505(2006)[hep-

Scaling study of the chiral phase transition in two-flavor QCD for the improved Wilson quarks at finite density H. Ohno for WHOT-QCD Collaboration The.

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

@ Brookhaven National Laboratory April 2008 Spectral Functions of One, Two, and Three Quark Operators in the Quark-Gluon Plasma Masayuki ASAKAWA Department.

Pion mass difference from vacuum polarization E. Shintani, H. Fukaya, S. Hashimoto, J. Noaki, T. Onogi, N. Yamada (for JLQCD Collaboration) December 5,

Study of chemical potential effects on hadron mass by lattice QCD Pushkina Irina* Hadron Physics & Lattice QCD, Japan 2004 Three main points What do we.

1 Lattice QCD, Random Matrix Theory and chiral condensates JLQCD collaboration, Phys.Rev.Lett.98,172001(2007) [hep-lat/ ], Phys.Rev.D76, (2007)

Huey-Wen Lin — Workshop1 Semileptonic Hyperon Decays in Full QCD Huey-Wen Lin in collaboration with Kostas Orginos.

Pion Correlators in the ε- regime Hidenori Fukaya (YITP) collaboration with S. Hashimoto (KEK) and K.Ogawa (Sokendai)

Lattice 2006 Tucson, AZT.Umeda (BNL)1 QCD thermodynamics with N f =2+1 near the continuum limit at realistic quark masses Takashi Umeda (BNL) for the RBC.

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.

The QCD phase diagram and fluctuations Deconfinement in the SU(N) pure gauge theory and Polyakov loop fluctuations Polyakov loop fluctuations in the presence.

Exact vector channel sum rules at finite temperature Talk at the ECT* workshop “Advances in transport and response properties of strongly interacting systems”

Deconfinement and chiral transition in finite temperature lattice QCD Péter Petreczky Deconfinement and chiral symmetry restoration are expected to happen.

QCD on Teraflops computerT.Umeda (BNL)1 QCD thermodynamics on QCDOC and APEnext supercomputers QCD thermodynamics on QCDOC and APEnext supercomputers Takashi.

Syo Kamata Rikkyo University In collaboration with Hidekazu Tanaka.

Dynamical Lattice QCD simulation Hideo Matsufuru for the JLQCD Collaboration High Energy Accerelator Research Organization (KEK) with.

Study of the structure of the QCD vacuum

Neutron Electric Dipole Moment at Fixed Topology

Nc=2 lattice gauge theories with

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

Spontaneous chiral symmetry breaking on the lattice

Speaker: Takahiro Doi (Kyoto University)

A novel probe of Chiral restoration in nuclear medium

Study of Aoki phase in Nc=2 gauge theories

Lattice QCD, Random Matrix Theory and chiral condensates

Lattice QCD in a fixed topological sector [hep-lat/ ]

Takashi Umeda (Hiroshima Univ.) for WHOT-QCD Collaboration

Neutron EDM with external electric field

Exact vector channel sum rules at finite temperature

Jun Nishimura (KEK, SOKENDAI) JLQCD Collaboration:

A possible approach to the CEP location

EoS in 2+1 flavor QCD with improved Wilson fermion

Presentation transcript:

Axial symmetry at finite temperature Guido Cossu High Energy Accelerator Research Organization – KEK Lattice Field Theory on multi-PFLOPS computers German-Japanese Seminar Nov 2013, Regensburg, Germany 高エネルギー加速器研究機構

U A (1) symmetry at finite temperature ✔ Introduction – chiral symmetry at finite temperature ✔ Simulations with dynamical overlap fermions ✔ Fixing topology ✔ Results: ✔ (test case) Pure gauge ✔ N f =2 case ✔ Other studies on the subject ✔ Conclusions, criticism and future work People involved in the collaboration: JLQCD group: H. Fukaya, S. Hashimoto, S. Aoki, T. Kaneko, H. Matsufuru, J. Noaki See Phys.Rev. D87 (2013) and previous Lattice proceedings ( ),

U A (1) symmetry at finite temperature Pattern of chiral symmetry breaking at low temperature QCD Symmetry of the Lagrangian Symmetries in the (pseudo)real world (N f =3) at zero temperature ● U(1) V the baryon number conservation ● SU(3) V intact (softly broken by quark masses) – 8 Goldstone bosons (GB) ● SU(3) A is broken spontaneously by the non zero e.v. of the quark condensate ● No opposite parity GB, U(1) A is broken, but no 9th GB is found in nature. Axial symmetry is not a symmetry of the quantum theory ('t Hooft - instantons) Witten-Veneziano : mass splitting of the  '(958) from topological charge at large N. topological charge density Finite temperature T > T c

U A (1) symmetry at finite temperature At finite temperature, in the chiral limit m q → 0, chiral symmetry is restored ● Phase transition at N f =2 (order depending on U(1) A see e.g. Vicari, Pelissetto) ● Crossover with 2+1 flavors What is the fate of the axial U(1) A symmetry at finite temperature T ≳ T c ? Complete restoration is not possible since it is an anomaly effect. Exact restoration is expected only at infinite T (see instanton-gas models) At most we can observe strong suppression (effective restoration) On the lattice the overlap Dirac operator is the best way to answer this questions since it preserves the maximal amount of chiral symmetry. An operator satisfying the Ginsparg-Wilson relation has several nice properties e.g. ● exact relation between zero eigenmodes (EM) and topological charge ● Negligible additive renormalization of the mass (residual mass) ●...

U A (1) symmetry at finite temperature Check the effective restoration of axial U(1) A symmetry by measuring (spatial) meson correlators at finite temperature in full QCD with the Overlap operator Degeneracy of the correlators is the signal that we are looking for (NB: 2 flavors) First of all there are some issues to solve before dealing with the real problem... Dirac operator eigenvalue density is also a relevant observable for chiral symmetry

U A (1) symmetry at finite temperature The sign function in the overlap operator gives a delta in the force when HW modes cross the boundary (i.e. topology changes), making very hard for HMC algorithms to change the topological sector In order to avoid expensive methods (e.g. reflection/refraction) to handle the zero modes of the Hermitian Wilson operator JLQCD simulations used (JLQCD 2006): ● Iwasaki action (suppresses Wilson operator near zero modes) ● Extra Wilson fermions and twisted mass ghosts to rule out the zero modes Topology is thus fixed throughout the HMC trajectory. The effect of fixing topology is expected to be a Finite Size Effect (actually O(1/V) ), next slides

U A (1) symmetry at finite temperature Partition function at fixed topology Using saddle point expansion around one obtains the Gaussian distribution where the ground state energy can be expanded (T=0)

U A (1) symmetry at finite temperature From the previous partition function we can extract the relation between correlators at fixed θ and correlators at fixed Q In particular for the topological susceptibility and using the Axial Ward Identity we obtain a relation involving fermionic quantities: P(x) is the flavor singlet pseudo scalar density operator, see Aoki et al. PRD76, (2007) What is the effect of fixing Q at finite temperature?

U A (1) symmetry at finite temperature ✔ Simulation details ✔ Finite temperature quenched SU(3) at fixed topology (proof of concept) ✔ Eigenvalues density distribution ✔ Topological susceptibility ✔ Finite temperature two flavors QCD at fixed topology ✔ Eigenvalues density distribution ✔ Meson correlators BG/L Hitachi SR16K

U A (1) symmetry at finite temperature Pure gauge (16 3 x6, 24 3 x6): Iwasaki action + topology fixing term Two flavors QCD (16 3 x8) Iwasaki + Overlap + topology fixing term O(300) trajectories per T, am=0.05, 0.025, 0.01 Pion mass: ~290 am=0.015, β =2.30 T c was conventionally fixed to 180, not relevant for the results (supported by Borsanyi et al. results) βa (fm)T (Mev)T/Tc βa (fm)T (Mev)T/Tc

U A (1) symmetry at finite temperature Phase transition

U A (1) symmetry at finite temperature Extracting the topological susceptibility: (Spatial) Correlators are always approximated by the first 50 eigenvalues Pure gauge: double pole formula for disconnected diagram Q=0, assume c 4 term is negligible, then check consistency Topological susceptibility estimated by a joint fit of connected and disconnected contribution to maximize info from data Cross check without fixing topology

U A (1) symmetry at finite temperature

Effect of axial symmetry on the Dirac spectrum If axial symmetry is restored we can obtain constraints on the spectral density Ref: S. Aoki, H. Fukaya, Y. Taniguchi Phys.Rev. D86 (2012)

U A (1) symmetry at finite temperature Test (β=2.20, am=0.01): decreasing Zolotarev poles in the approx. of the sign function At N poles = 5 more near zero modes appeared (16 is the number used in the rest of the calculation)

U A (1) symmetry at finite temperature Bazavov et al Updated 2013 (HotQCD) DWF Low modes Vranas 2000 DWF No restoration Ohno et al Updated 2013 HISQ (2+1)

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Mass Temperature

U A (1) symmetry at finite temperature Disconnected contibution at β=2.30 and several distances Falls faster than exponential

U A (1) symmetry at finite temperature Full QCD spectrum shows a gap at high temperature even at pion masses ~250 MeV Statistics: high at T>200 MeV Correlators show degeneracy of all channels when mass is decreased Results support effective restoration of U(1) A symmetry With overlap fermions we have a clear theoretical setup for the analysis of spectral density and control on chirality violation terms. Realistic simulations are possible, but topology must be fixed A check of systematics due to topology fixing at finite temperature is necessary (finite volume corrections are expected) Pure gauge test results show that we can control these errors as in the previous T=0 case. Finite volume effects are small in the SU(3) pure gauge case Criticism, systematics (the usual suspects): Finite volume effects (beside topology fixing): only one volume Lowest mass still quite large (HotQCD addresses this) No continuum limit Future work (ongoing): New action, DWF with scaled Shamir kernel: very low residual mass ~0.5, no topology fix Two volumes(at least), lower masses Systematic check for dependence of results on the sign function approximation Criticism, systematics (the usual suspects): Finite volume effects (beside topology fixing): only one volume Lowest mass still quite large (HotQCD addresses this) No continuum limit Future work (ongoing): New action, DWF with scaled Shamir kernel: very low residual mass ~0.5, no topology fix Two volumes(at least), lower masses Systematic check for dependence of results on the sign function approximation

U A (1) symmetry at finite temperature LuxRay Artistic Rendering of Lowest Eigenmode

U A (1) symmetry at finite temperature Backup slides

U A (1) symmetry at finite temperature Lowest Eigenmode