Presentation is loading. Please wait.

Presentation is loading. Please wait.

quark angular momentum in lattice QCD

Published byDeddy Darmadi Modified over 5 years ago

Similar presentations

Presentation on theme: "quark angular momentum in lattice QCD"— Presentation transcript:

1 quark angular momentum in lattice QCD
Munehisa Ohtani ( Kyorin Univ., Regensburg Univ.) for UKQCD-QCDSF collab. with D. Brömmel, M. Göckeler, Ph. Hägler, R. Horsley, Y. Nakamura, D. Pleiter, P.E.L. Rakow, A. Schäfer, G. Schierholz, W. Schroers, H. Stüben, J.M. Zanotti Introduction Form Factors and Observables Numerical results of lattice simulation - Axial FF and quark spin - Moments of GPD(vector) and total angular momentum Summary 8 Apr. RIKEN

2 Introduction Non perturbative study on Nucleon structure
 Generalized Parton Distributions of Nucleon q q' momentum transfer squared: t = (D  P'-P)2 longitudinal mt. transfer:  = -n ·D / 2 x+ x- H, E, … P P' Non perturbative study on Nucleon structure

3 Generalized Parton Distributions
PDF Form Factors F1(t) =  dx H (x, x, t) GA(t) =  dx H (x, x, t) GT(t) =  dx HT(x, x, t) local limit q(x) Dq(x) dq(x) = H (x,0,0) = HT(x,0,0) forward limit GPDs J q = 1/2  dx x (H(x, x, 0) + E(x, x, 0)) u+d  1/2 ( A20 + B20 ) s q = 1/2  dx H(x, x, 0)u+d  1/2 A10 Angular momentum as moments in the forward limit Fourier transf. Quark density in b plane q(x, b2) =  d2 D e–i Db H (x, x=0, D2)

4 Moments of GPD: Generalized Form Factors
 Polynomiality  X.-D.Ji, J.Phys.G24(1998)1181 An,2k , Bn,2k , Cn are related to  P |q g {m 1Dm 2  Dm n}q |P'   LHPC, PRD68(2003)034505 Calculate ratio of 2pt & 3pt correlation functions on lattice Extract GFF Vector current, EM tensor

5 Simulation parameters
b k volume a [fm] mp[GeV]  Nf =2 Wilson fermions w/ clover improvement  # of config: for each(b,k)  Physical unit translated by r0c / a O(a) improved operators  non-perturbative renormalization into m = 2 GeV 5.20 0.0856 163  32 1.347 0.956 0.670 5.25 0.0794 1.225 0.949 0.635 0.457 243  48 163  32 5.29 0.0753 1.511 1.102 0.857 0.629 0.414 0.345 243  48 323  64 5.40 0.0672 243  48 1.183 0.917 0.648 0.559 0.450

6 t dependence of Axial Form Factor
 V.Bernard et.al. J.Phys.G 28(2002)R1 cf. A10u-d from expt: p + e  e' + p + + n A10u+d (t) with b = 5.29,k = Dipole form: A10  -t [GeV2]

7 Chiral extrapolation and quark spin
A10u+d (t=0) : 2 s u+d = DSu+d  0.024 mp = .14GeV) Strong mp dependence by “chiral log” term HERMES, PRD75(2007)  Heavy Baryon Chiral Perturbation Theory  M.Diehl, A.Manashov, A.Schäfer, EPJ.A 29(2006) mp 2[GeV2]

8 t dependence of the 2nd Moments
A20u-d (t), B20u-d (t) and C20u-d (t) with b = 5.29,k = -t [GeV2]

9 Dipole mass of A20 and tensor meson
mD [GeV] Dipole form: A20  x (1 - t / mD2)2 in CQSM for comparison  K. Goeke et. al., PRC75(2007) Observed mass of f2

10 Chiral extrapolation of A20u+d(t =0)
 M.Dorati et.al. nucl-th/ A20u+d (t=0)  x u+d  0.012 mp = .14GeV)  CTEQ6 @m 2 = 4GeV2 mp 2[GeV2]

11 Chiral extrapolation of A20u-d(t =0)
 x u-d  0.008 mp = .14GeV) A20u-d (t=0)  CTEQ6 @m 2 = 4GeV2 Strong mp dependence by “chiral log” term mp 2[GeV2]

12 Generalized Form Factors in Chiral Perturbation
 M.Dorati, T.A.Gail and T.R.Hemmert, nucl-th/  3 param. in each GFFs  t dependence via

13 Dipole fit and forward limit of B20u,d(t )
 2 J q -  x q t  0 B20q (t) in CQSM  J u+d = 1/2  x u+d = 1 ) no dynamical gluon  K.Goeke et. al., PRC75(2007) in CQSM for comparison -t [GeV2]

14 B20u+d( t ) and covariantized Baryon ChPT

15 Chiral extrapolation of B20u+d(0)
mp = .14GeV) B20u+d (0) Strong mp dependence by “chiral log” term mp 2[GeV2]

16 B20u-d(t ) and covariantized Baryon ChPT

17 Chiral extrapolation of B20u-d(0)
mp = .14GeV) B20u-d (0) mp 2[GeV2]

18 Chiral extrapolation of Ju , Jd
Ji’s sum rule :  J q = 1/2 [ A20q (0) +B20q(0) ]  J u  0.008  J d  0.008 mp = .14GeV) mp 2[GeV2]

19 decomposition of quark angular momentum
J u+d = 1/2 [ A20u+d (0) +B20u+d(0) ]  s u+d = 1/2 A10u+d (0) ; Lu+d =  J u+d -  s u+d  J u+d  0.013  s u+d  0.024  L u+d  0.027 mp = .14GeV) mp 2[GeV2]

20 Summary and outlook lattice simulation of moments of Generaized Parton Distribution  spin content, transverse quark distribution, DVCS,… dipole mass of A20 is comparable with tensor meson mass. A20u-d and B20u+d have strong “chiral log” corrections. Chiral extrapolation of A20 (0) & B20 (0) via BChPT nucl-th/ leads  J u  0.008  J d  0.008 lighter mp , larger volume (for t 0), Finite size corrections, Continuum limit, disconnected diagram, Chirally improved fermions, higher twist, angular momentum of gluon, …  J u+d  0.013  s u+d  0.024 mp = .14GeV)  L u+d  0.027

Download ppt "quark angular momentum in lattice QCD"

Similar presentations

Lattice study for penta-quark states

Lattice study for penta-quark states
Mass, Quark-number, Energy Dependence of v 2 and v 4 in Relativistic Nucleus- Nucleus Collisions Yan Lu University of Science and Technology of China Many.

Mass, Quark-number, Energy Dependence of v 2 and v 4 in Relativistic Nucleus- Nucleus Collisions Yan Lu University of Science and Technology of China Many.
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.

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.
A status report of the QCDSF N f =2+1 Project Yoshifumi Nakamura (NIC/DESY) for the QCDSF collaboration Lattice Regensburg Aug. 3, 2007.

A status report of the QCDSF N f =2+1 Project Yoshifumi Nakamura (NIC/DESY) for the QCDSF collaboration Lattice Regensburg Aug. 3, 2007.
The N to Delta transition form factors from Lattice QCD Antonios Tsapalis University of Athens, IASA EINN05, Milos, 21-9-2005.

The N to Delta transition form factors from Lattice QCD Antonios Tsapalis University of Athens, IASA EINN05, Milos,
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.

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.
Xiangdong Ji University of Maryland/SJTU Physics of gluon polarization Jlab, May 9, 2013.

Xiangdong Ji University of Maryland/SJTU Physics of gluon polarization Jlab, May 9, 2013.
9/19/20151 Nucleon Spin: Final Solution at the EIC Feng Yuan Lawrence Berkeley National Laboratory.

9/19/20151 Nucleon Spin: Final Solution at the EIC Feng Yuan Lawrence Berkeley National Laboratory.
Finite Density with Canonical Ensemble and the Sign Problem Finite Density Algorithm with Canonical Ensemble Approach Finite Density Algorithm with Canonical.

Finite Density with Canonical Ensemble and the Sign Problem Finite Density Algorithm with Canonical Ensemble Approach Finite Density Algorithm with Canonical.
Spin Azimuthal Asymmetries in Semi-Inclusive DIS at JLAB  Nucleon spin & transverse momentum of partons  Transverse-momentum dependent distributions.

Spin Azimuthal Asymmetries in Semi-Inclusive DIS at JLAB  Nucleon spin & transverse momentum of partons  Transverse-momentum dependent distributions.
XI th International Conference on Quark Confinement and the Hadron Petersburg, Russia 8.9.2014 Philipp Gubler (RIKEN, Nishina Center) Collaborator:

XI th International Conference on Quark Confinement and the Hadron Petersburg, Russia Philipp Gubler (RIKEN, Nishina Center) Collaborator:
Eigo Shintani (KEK) (JLQCD Collaboration) KEKPH0712, Dec. 12, 2007.

Eigo Shintani (KEK) (JLQCD Collaboration) KEKPH0712, Dec. 12, 2007.
Beta-function as Infrared ``Phenomenon” RG-2008 (Shirkovfest) JINR, Dubna, September 1 2008 Oleg Teryaev JINR.

Beta-function as Infrared ``Phenomenon” RG-2008 (Shirkovfest) JINR, Dubna, September Oleg Teryaev JINR.
Generalized Form Factors, Generalized Patron Distributions, and Spin Contents of the Nucleon with Y. Nakakoji (Osaka Univ.) 1. Introduction - Still unsolved.

Generalized Form Factors, Generalized Patron Distributions, and Spin Contents of the Nucleon with Y. Nakakoji (Osaka Univ.) 1. Introduction - Still unsolved.
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.

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.
Jim Stewart DESY Measurement of Quark Polarizations in Transversely and Longitudinally Polarized Nucleons at HERMES for the Hermes collaboration Introduction.

Jim Stewart DESY Measurement of Quark Polarizations in Transversely and Longitudinally Polarized Nucleons at HERMES for the Hermes collaboration Introduction.
Pion mass difference from vacuum polarization E. Shintani, H. Fukaya, S. Hashimoto, J. Noaki, T. Onogi, N. Yamada (for JLQCD Collaboration) December 5,

Pion mass difference from vacuum polarization E. Shintani, H. Fukaya, S. Hashimoto, J. Noaki, T. Onogi, N. Yamada (for JLQCD Collaboration) December 5,
大西 陽一 (阪 大) QCDの有効模型に基づく光円錐波動関数を用い た 一般化パートン分布関数の研究 若松 正志 (阪大)

大西 陽一 (阪 大) QCDの有効模型に基づく光円錐波動関数を用い た 一般化パートン分布関数の研究 若松 正志 (阪大)
Measurements with Polarized Hadrons T.-A. Shibata Tokyo Institute of Technology Aug 15, 2003 Lepton-Photon 2003.

Measurements with Polarized Hadrons T.-A. Shibata Tokyo Institute of Technology Aug 15, 2003 Lepton-Photon 2003.
Huey-Wen Lin — Workshop1 Semileptonic Hyperon Decays in Full QCD Huey-Wen Lin in collaboration with Kostas Orginos.

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

Similar presentations

Ads by Google