Half-Skyrmion Matter & Quarkionic Matter HIM-WCU workshop Hanyang U. Oct. 31, 2009 Byung-Yoon Park (Chungnam Nat’l Univ.)

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Presentation transcript:

Half-Skyrmion Matter & Quarkionic Matter HIM-WCU workshop Hanyang U. Oct. 31, 2009 Byung-Yoon Park (Chungnam Nat’l Univ.)

Collaborators M. Rho(Saclay, Hanyang Univ.) V. Vento(Valencia Univ.) D.-P. Min(Seoul National Univ.) H.-J. Lee(Chungbuk National Univ.)

Contents 1.Skyrme Model ? 2. Dense Skyrmion Matter 3. Dense & Hot Skyrmion Matter 4. Summary

1. Skyrme Model?

Skyrmion Model U(x) : mapping from R 3 -{ }=S 3 to SU(2)=S 3 8 topological soliton 1960, T. H. R. Skyrme R ~ 1 f m M ~ 1.5 GeV BARYON ?

protonneutron 1919 Rutherford 1932 Chadwick pion protonneutron 1935 Yukawa Hadronic World (Skyrmionist’s Viewpoint) pion 1960 Skyrme

SU(2) Collective Coord. Quantization N,  SU(3) collective Coordinate Quatization  ,  * 

 ,  *  Hedgehog Soliton SU(2) collective Coordinate Quatization bound kaon

 c  ,  *  *  c Hedgehog Soliton SU(2) collective Coordinate Quatization bound D,D* c c

Multi-Skyrmion system B=2 Torus B=3 Tetrahedron B=4 Cube B=5 with D d2 sym B=6 with D d4 sym B=7 Dodecahedron

Toroidal B=2 skyrmion 1988, Braaten & Carson, 1995, Leese, Manton & Schroers

2. Dense Skyrmion Matter

2. Dense Skyrmion matter

Two skyrmions in the most attractive configuration. 2. Dense Skyrmion matter

1985, I. Klebanov (E/B) min =1.078 at L C =5.56 Simple Cubic Skyrmion Crystal U(x+L C,y,z) =  y U(x,y,z)  y y Y z xz x x x X y LCLC o 2. Dense Skyrmion matter

Half-Skyrmion Crystal U(x+L C,y,z) =  y U(x,y,z)  y 1987, A. S. Goldhaber & N. S. Manton + additional Symmetry w.r.t.   -  (E/B) min =1.076 at L C =5.56 y zx X LCLC  =-1  =+1 (L b /2 above) 0 2. Dense Skyrmion matter

U = exp(i  F(r)  r ) ^. Half-skyrmion? F (r )F (r ) r  U =-1 2. Dense Skyrmion matter

U =-1 U =+1 2. Dense Skyrmion matter

U =-1 U =+1 2. Dense Skyrmion matter

B=4 skyrmion 2. Dense Skyrmion matter

1989, L. Castellejo et al. & M. Kulger et al. y Y x x X y z=L F /2 plane Y o z z z X z LFLF z=0 plane FCC Skyrmion Crystal 2. Dense Skyrmion matter

Y X (E/B) min =1.038 at L f =4.72 o z Y z z X z LFLF y x x y Half-Skyrmion CC 2. Dense Skyrmion matter

E/B vs. L F 2. Dense Skyrmion matter

= Chiral symmetry restoration in dense matter? 2. Dense Skyrmion matter

static soliton config. fluctuating pions Pion in the dense baryonic matter? classical dense matter config. 2. Dense Skyrmion matter

Skyrme Model ( m  =0 ) \ Pion fluctuation in  B =0 space Vacuum : U=1 2. Dense Skyrmion matter

 dynamics (  =0) \ +  - skyrmion matter interactions Skyrmion matter Pion fluctuations on top of the skyrmion matter 2. Dense Skyrmion matter

 dynamics (  =0) \ 2. Dense Skyrmion matter

 dynamics (  =0) \ 2. Dense Skyrmion matter

 dynamics (  =0) \ In-Medium pion decay constant ? In-Medium pion mass ? 2. Dense Skyrmion matter

pion effective mass H.-J. Lee, B.-Y. Park, D.-P. Min, M. Rho, V. Vento, Nucl. Phys. A (2003) ! 2. Dense Skyrmion matter

ff   Pseudogap? Zarembo, hep-ph/ U still remains on the Chiral Circle But =0 Chiral Symmetry Restoration 2. Dense Skyrmion matter

Skyrme Lagrangian Trace Anomaly of QCD 2. Dense Skyrmion matter

Skyrme Lagrangian Ellis & Lanik, PLB(1985) Brown-Rho scaling, PRL(1992) m  ~ 720 MeV, f  ~240 MeV 2. Dense Skyrmion matter

ff  V  Vacuum (  =0) U=1  =f  ff   <><> U  U 2. Dense Skyrmion matter

Naive Estimation E/B=M 2 (L)  2 +M 4 (L) +M m (L)  3 +V(  )L 3 2. Dense Skyrmion matter

Naive Estimation 2. Dense Skyrmion matter

E/B =0 phase Chiral phase transition =0 phase / 2. Dense Skyrmion matter

 & <><> <><> Pseudogap Phase?  S Phase  SB Phase m  =0 2. Dense Skyrmion matter

 Pseudogap still remains? ff  ff   * *  SB Phase Pseudogap Phase  S Phase   2. Dense Skyrmion matter

3. Hot & Dense Skyrmion Matter

? 2. Hot & Dense Skyrmion matter

Skyrmion Soup Condiments : dilaton vector mesons Heat Main ingredients : pions B.-Y. Park, H.-J. Lee, V. Vento, Phys. Rev. D80 (2009) 2. Hot & Dense Skyrme matter

Skyrmion from Instanton 1989, M. F. Atiyah & N. S. Manton time component of SU(2) gauge potential for the instanton field of charge N time-ordering constant matrix to make U approaches 1 at infinity constant rotation matrix 2. Hot & Dense Skyrmion matter

E/B vs. L F 2. Hot & Dense Skyrmion matter

B.-Y. Park, D.-P. Min, V. Vento & M. Rho, Nucl. Phys. A707(2002) Hot & Dense Skyrmion matter

B.-Y. Park, D.-P. Min, V. Vento & M. Rho, Nucl. Phys. A707(2002) Hot & Dense Skyrmion matter

Pion Gas! P = T 4  2 30 E/B = 3PV E/B=(M 2 (  )+3PV)  2 +M 4 (  ) +V(  )/  1/3 2. Hot & Dense Skyrmion matter

Conclusion 2. Hot & Dense Skyrmion matter

Summary Skyrme Model can be applied to study (1) dense hadronic matter (2) hadron properties in dense matter 4. Summary

Thank You!