Lattice QCD and Nuclear Physics Martin Savage University of Washington Lattice 2005, Dublin, July 2005.

Slides:

Advertisements

Similar presentations

1 Eta production Resonances, meson couplings Humberto Garcilazo, IPN Mexico Dan-Olof Riska, Helsinki … exotic hadronic matter?

Advertisements

Delta-hole effects on the shell evolution of neutron-rich exotic nuclei Takaharu Otsuka University of Tokyo / RIKEN / MSU Chiral07 Osaka November 12 -

Nucleon Axial and Nucleon-to-Delta Axial Transition Form Factors from Lattice QCD A. Tsapalis Institute of Accelerating Systems and Applications University.

Possible existence of neutral hyper-nucleus with strangeness -2 and its production SPN 2014, Changsha, Dec , 2014 Institute of High Energy Physics.

Kab/SC-PAC Operated by the Southeastern Universities Research Association for the U.S. Department of Energy Thomas Jefferson National Accelerator.

M. Lujan Hadron Electric Polarizability with n-HYP Clover Fermions Michael Lujan Andrei Alexandru, Walter Freeman, and Frank Lee The George Washington.

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,

P461 - Nuclei I1 Properties of Nuclei Z protons and N neutrons held together with a short-ranged force  gives binding energy P and n made from quarks.

5/20/2015v. Kolck, Halo EFT1 Background by S. Hossenfelder Halo Effective Field Theory U. van Kolck University of Arizona Supported in part by US DOE.

16/3/2015 Baryon-Baryon Interactions From Lattice QCD Martin Savage University of Washington K  (Hyperons 2006, Mainz, Germany)

Hadrons and Nuclei : Introductory Remarks Lattice Summer School Martin Savage Summer 2007 University of Washington.

Scadron70 page 1 Pattern of Light Scalar Mesons a 0 (1450) and K 0 *(1430) on the Lattice Tetraquark Mesonium – Sigma (600) on the Lattice Pattern of Scalar.

Two talks for the price of one: Cooling by angulon annihilation and Asymmetrical fermion superfluids P. Bedaque (Berkeley Lab) G. Rupak, M. Savage, H.

Table of contents 1. Motivation 2. Formalism (3-body equation) 3. Results (KNN resonance state) 4. Summary Table of contents 1. Motivation 2. Formalism.

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

P461 - Nuclei I1 Properties of Nuclei Z protons and N neutrons held together with a short-ranged force  gives binding energy P and n made from quarks.

Lattice 07, Regensburg, 1 Magnetic Moment of Vector Mesons in Background Field Method Structure of vector mesons Background field method Some results x.

QUARKS, GLUONS AND NUCLEAR FORCES Paulo Bedaque University of Maryland, College Park.

Hadrons and Nuclei : Scattering Lattice Summer School Martin Savage Summer 2007 University of Washington.

Opportunities for low energy nuclear physics with rare isotope beam 현창호 대구대학교 과학교육학부 2008 년 11 월 14 일 APCTP.

Nuclear Symmetry Energy from QCD Sum Rule Phys.Rev. C87 (2013) Recent progress in hadron physics -From hadrons to quark and gluon- Feb. 21, 2013.

New States of Matter and RHIC Outstanding questions about strongly interacting matter: How does matter behave at very high temperature and/or density?

1 Multi-nucleon bound states in N f =2+1 lattice QCD T. Yamazaki 1), K.-I. Ishikawa 2), Y. Kuramashi 3,4), A. Ukawa 3) 1) Kobayashi-Maskawa Institute,

C-REX (little sister of PREX) : Parity-Violating Measurement of the Weak Charge radius of 48 Ca to 0.03 fm. 1-pass (2.2 GeV) HRS + septum C-REX Workshop.

J/ψ - bound nuclei and J/ψ - nucleon interaction Akira Yokota Tokyo Institute of Technology Collaborating with Emiko Hiyama a and Makoto Oka b RIKEN Nishina.

横田朗A 、肥山詠美子B 、岡眞A 東工大理工A、理研仁科セB

Charm hadrons in nuclear medium S. Yasui (KEK) K. Sudoh (Nishogakusha Univ.) “Hadron in nucleus” 31 Nov. – 2 Dec arXiv:1308:0098 [hep-ph]

Toshitaka Uchino Tetsuo Hyodo, Makoto Oka Tokyo Institute of Technology 10 DEC 2010.

Dense Stellar Matter Strange Quark Matter driven by Kaon Condensation Hyun Kyu Lee Hanyang University Kyungmin Kim HKL and Mannque Rho arXiv:

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.

Assumpta Parreño NPLQCD Collaboration HYP-XInternational conference of hypernuclear physics, JPARC, Ibaraki, JAPAN Sep. 14- Sep

L. R. Dai (Department of Physics, Liaoning Normal University) Z.Y. Zhang, Y.W. Yu (Institute of High Energy Physics, Beijing, China) Nucleon-nucleon interaction.

Hadron - Hadron Interactions 12 GeV  and Lattice QCD --- Martin Savage Color Transparancy --- Jean-Marc Laget Presentation…… November 5, 2004,

LBL 5/21/2007J.W. Holt1 Medium-modified NN interactions Jeremy W. Holt* Nuclear Theory Group State University of New York * with G.E. Brown, J.D. Holt,

H. Lenske Institut für Theoretische Physik, U. Giessen Aspects of SU(3) Flavor Physics In-medium Baryon Interactions Covariant Density Functional Theory.

Second Berkeley School on Collective Dynamics, May 21-25, 2007 Tetsuo Hatsuda, Univ. Tokyo PHYSICS is FUN LATTICE is FUN [1] Lattice QCD basics [2] Nuclear.

F. Sammarruca, University of Idaho Supported in part by the US Department of Energy. From Neutron Skins to Neutron Stars to Nuclear.

High Energy Nuclear Physics and the Nature of Matter Outstanding questions about strongly interacting matter: How does matter behave at very high temperature.

Study of light kaonic nuclei with a Chiral SU(3)-based KN potential A. Dote (KEK) W. Weise (TU Munich)  Introduction  ppK - studied with a simple model.

Limits of applicability of the currently available EoS at high density matter in neutron stars and core-collapse supernovae: Discussion comments Workshop.

Chiral phase transition and chemical freeze out Chiral phase transition and chemical freeze out.

Particles and how they interact

Two particle states in a finite volume and the multi-channel S- matrix elements Chuan Liu in collaboration with S. He, X. Feng Institute of Theoretical.

Nuclear Symmetry Energy from QCD Sum Rule The 5 th APFB Problem in Physics, August 25, 2011 Kie Sang JEONG Su Houng LEE (Theoretical Nuclear and Hadron.

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

Probing TeV scale physics in precision UCN decays Rajan Gupta Theoretical Division Los Alamos National Lab Lattice 2013 Mainz, 30 July 2013 Superconducting.

R. Machleidt, University of Idaho Recent advances in the theory of nuclear forces and its relevance for the microscopic approach to dense matter.

Furong Xu （许甫荣） Many-body calculations with realistic and phenomenological nuclear forces Outline I. Nuclear forces II. N 3 LO (LQCD): MBPT, BHF, GSM (resonance.

Lawrence Livermore National Laboratory Lattice QCD and Nuclear physics From Pipe Dream to Reality June 22, 2009 Tom Luu Performance Measures x.x, x.x,

Time Dependent Quark Masses and Big Bang Nucleosynthesis Myung-Ki Cheoun, G. Mathews, T. Kajino, M. Kusagabe Soongsil University, Korea Asian Pacific Few.

Hadronic Form-Factors Robert Edwards Jefferson Lab Abstract: A TECHNOLOGY TALK!! Outline a known but uncommon method in 3-pt function calculations that.

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.

Collaborators: Bugra Borasoy – Bonn Univ. Thomas Schaefer – North Carolina State U. University of Kentucky CCS Seminar, March 2005 Neutron Matter on the.

Furong Xu （许甫荣） Nuclear forces and applications to nuclear structure calculations Outline I. Nuclear forces II. N 3 LO (LQCD): MBPT, BHF, GSM (resonance.

Physics with Medium Energy (>100 MeV) Gamma-Rays Blaine Norum University of Virginia 10/16/15 FACET II Science Workshop Physics with Medium Energy (>100.

Nuclear Physics, JU, Second Semester,

Dynamical Anisotropic-Clover Lattice Production for Hadronic Physics A. Lichtl, BNL J. Bulava, J. Foley, C. Morningstar, CMU C. Aubin, K. Orginos, W&M.

Kab/SC-PAC Operated by the Southeastern Universities Research Association for the U.S. Department of Energy Thomas Jefferson National Accelerator.

INTRODUCTION TO NUCLEAR LATTICE EFFECTIVE FIELD THEORY Young-Ho Song (RISP, Institute for Basic Science) RI meeting, Daejeon,

Electric Dipole Response, Neutron Skin, and Symmetry Energy

May the Strong Force be with you

Structure of the Proton mass

Tensor optimized shell model and role of pion in finite nuclei

Hadrons and Nuclei : Chiral Symmetry and Baryons

Aspects of the QCD phase diagram

Excited State Spectroscopy from Lattice QCD

p, KK , BB from Lattice QCD Martin Savage Univ. of Washington

Hadrons and Nuclei : Nuclear Physics

Excited State Spectroscopy from Lattice QCD

Effects of the φ-meson on the hyperon production in the hyperon star

Presentation transcript:

Lattice QCD and Nuclear Physics Martin Savage University of Washington Lattice 2005, Dublin, July 2005

Emergence of Nuclear Physics from QCD Consistent and rigorous pathway from QCD Lattice QCD EFT Many-Body Lattice QCD EFT Many-Body M q - explicit

Calculations where experiments are not possible Supernova Remnant ? neutron stars  - decay …  - decay … nn , K or black holes, or black holes, ….. kaon condensation ? …..

How does nature depend upon the fundamental constants? Quark mass dependence of element production Dependence upon 

Understand the fine-tunings of nature Deuteron Binding energy is ~2.2 MeV a(1s0) ~ -24 fm Infrared fixed-point of QCD Infrared fixed-point of QCD 3  12 C Short-range repulsion Intermediate-range attraction Long-range attraction (s-wave) NN Potential  - exchange  - exchange ??? N N N N NN NN  ~

NN-Scattering (s-wave) M q –dependence of nuclear properties – Little is known……..this is all !!! Quenched Data (Fukugita et al, 1995), Latt = 20 4 A Lattice Measurement at this m  would fix counterterms : D 2 1S01S0 3S13S1

Nuclear Physics with lattice QCD University of New Hampshire Lawrence Berkeley Laboratory College of William and Mary University of Groningen University of Barcelona University of Washington

Maiani-Testa: End of the Innocence  (s) ? G NN (s) Euclidean = G NN (s) Minkowski One Hoped that Away from Kinematic Thresholds at infinite volume

Two-Particle Energy Levels (Luscher) UV regulator Below Inelastic Thresholds :

Calc. in Pionless EFT :5 fm lattices or larger for M = 140 MeV Calc. in Pionless EFT :5 fm lattices or larger for M  = 140 MeV Need Pionful theory calc. for smaller lattices M = 350 MeV 2.5 fm lattices.... MILC lattices M  = 350 MeV 2.5 fm lattices.... MILC lattices NN on the Lattice ~E L 2 Deuteron 1st continuum 2nd continuum Don’t Need Huge Lattices !!!!

np d  NN NN NN  11 l1l1 MEC’s Asymmetric Lattice (William Detmold and MJS)

ElectroWeak Matrix Elements L X L/10 X L/10 X T lattice

Hyperon Weak Interactions S-waveP-wave Lattice surface term ( Orginos )

 Q  Q Potential

NPLQCD Current Resources : SciDAC JLab Clusters – 8% resources ~ 40 Gflop-yrs Chroma / QDP++ MILC staggered Lattices DWF Propagators of LHPC Approved Exploratory NN,  NN,  M N -  term, strong-isospin-breaking (PQ) M N -  term, strong-isospin-breaking (PQ)

 scattering LHPC’s DWF valence propagators on 20 3 X 64 MILC staggered sea M   and 290 MeV

Chiral-Extrapolation M  a 2 = (  PT for  by Bijnens, Colangelo, Gasser, Leutwyler, …)

 Prelim. Coupled Channels ? | a | < 1 fm

Conclusion Lattice QCD studies of Nuclei and Multi-Hadron Systems are an important part of the future of Nuclear Physics. Lattice QCD studies of Nuclei and Multi-Hadron Systems are an important part of the future of Nuclear Physics.

Topics that are or can or should be tackled today Nucleon Properties … (LHPC) M N,  N, g A,  , as functions of m q, a, V M N,  N, g A,  , as functions of m q, a, V The NN Systems …  (s), L A 1,..  (s), L A 1,.. Hyperon Properties and Systems… M ,  N ,  N  N,   .. M ,  N ,  N  N,   .. V(R) between Hadrons with one Q : DD (Michael, Cook+Fiebig,…) 