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Thermodynamics and Z(N) interfaces in large N matrix model RIKEN BNL Shu Lin SL, R. Pisarski and V. Skokov, arXiv:1301.7432arXiv:1301.7432 1 YITP, Kyoto.

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Presentation on theme: "Thermodynamics and Z(N) interfaces in large N matrix model RIKEN BNL Shu Lin SL, R. Pisarski and V. Skokov, arXiv:1301.7432arXiv:1301.7432 1 YITP, Kyoto."— Presentation transcript:

1 Thermodynamics and Z(N) interfaces in large N matrix model RIKEN BNL Shu Lin SL, R. Pisarski and V. Skokov, arXiv:1301.7432arXiv:1301.7432 1 YITP, Kyoto 11/18

2 Outline A brief review of matrix model Solution of matrix model in large N limit Construct order-disorder and order-order interfaces and calculate the corresponding interface tensions 1/N correction to solution of matrix model Numerical results on the nonmonotonic behavior as a function of N Summary&Outlook

3 SU(N) deconfinement phase transition SU(2)second order SU(N  3) first order Trace anomaly M. Panero, Phys.Rev.Lett. (2009)

4 More on trace anomaly  ~ T 2 ? M. Panero, Phys.Rev.Lett. (2009)

5 SU(N) matrix model Deconfinement phase transition order parameter: Variables of matrix model: q i V pt ~ T 4 V non ~ T 2 T c 2 A. Dumitru, Y. Guo, Y. Hidaka, C. Korthals, R. Pisarski, Phys.Rev. D (2012)

6 SU(N) matrix model For SU(N) group -1/2  q  1/2

7 SU(N) matrix model T>>Td, V pt dorminates, perturbative vacuum: T<Td, confined vacuum driven by V non :

8 SU(N) matrix model Three parameters in nonperturbative potential Two conditions: T c is the transition tempeprature; pressure vanishes at T c Free parameters determined by fitting to lattice data Analytically solvable for two and three colors Numerically solvable for higher color numbers

9 Fitting to lattice data Fitting for SU(3)

10 Fitting to lattice data Polyakov loop l(T) Too sharp rise!! ‘t Hooft loop, order-order interface tension

11 Matrix model in the large N limit with Eigenvalue density Minimize V tot (q) with respect to  (q) subject to Consider symmetric distribution due to Z(N) symmetry In terms of  (q), V tot (q) becomes polynomial interaction of many body system Sovable! Pisarski, Skokov PRD (2012)

12 First or second order phase transition? second? first? second? first? discontinuous

13 Distribution of eigenvalues T<T d, confined T>T d, deconfined T=T d, transition  (  q 0 )=0 Critical distribution identical to 2D U(N) LGT at phase transition—Gross-Witten transition!

14 Construction of Z(N) vacua apply Z(N) transform to the symmetric distribution relabel  =k/N Order-order interface is defined as a domain wall interpolating two Z(N) inequivalent vacua above T d Order-disorder interface is defined as a domain wall interpolating confined and deconfined vacua at T d Order-order interface tension can be related to VEV of spatial ‘t Hooft loop C. Korthals, A. Kovner and M. Stephanov, Phys Lett B (1999)

15 Zero modes of the potential at T=T d  =1+b cos2  q “b mode” b=0b=1 “  mode” Emergent zero modes at naive large N limit

16 Construction of order-disorder interface Kinetic energy: Use b-mode for the order-disorder interface: potential energy V(q) vanishes For an interface of length L, kinetic energy K(q) ~ 1/L vanishes in the limit Interface tension   (K(q)+V(q))/L vanishes for order-disorder interface

17 Construction of order-order interface at T=T d confineddeconfined part I part II: Z(N) transform of part I confineddeconfined Second possibility, use of  mode:  (z)  =0  0 Ruled out by divergent kinetic energy q 

18 Construction of order-order interface at T>T d Limiting cases: T>T d, eigenvalue distribution gapped: eigenvalues q do not occupy the full range [-1/2,1/2] near confineddeconfined part I part III: Z(N) transform of part I near confineddeconfined part II q  dependence on  obtained using ansatz of the interface

19 Construction of order-order interface at T>T d Another limiting case: V ~  (1-2q 0 ) 4, K ~  (1-2q 0 ) 2 Compare with the other limiting case Noncommutativity of the two limits Recall  =k/N Noncommutativity of large N limit and Important to consider 1/N correction!

20 Comparison with weak&strong coupling results SYM strong coupling Bhattaharya et al PRL (1992) Armoni, Kumar and Ridgway, JHEP (2009) Yee, JHEP (2009) SU(N) weak coupling SS model

21 1/N correction of thermodynamics Euler-MacLaurin formula variation

22 1/N corrected eigenvalue distribution to the order 1/N solution Imaginary part of Polyakov loop vanishes to order 1/N!

23 Comparison with numerics 1/N expansion breaks down. Numerical results suggest correction is organizied as

24 1/N correction to potential At T=T d, height of potential barrier can be obtained from numerical simulation potential normalized by 1/(N 2 -1): barrier shows nonmonotoic behavior in N. maxiam at roughly N=5 tail Correction to interface tension at T=Td

25 Summary&Outlook Large N matrix model phase transition resembles that of Gross-Witten. In naive large N limit, interface tension vanishes at T=T d. Above T d, nontrivial dependence on T. Large N and phase transition limit do not commute. 1/N correction to the thermodynamics needed. It breaks down at T d. Numerical simulation shows nonmonotonic behavior in potential barrier as a function of N Magnetic degree of freedom?

26 Thank you!

27 mean field approximation? Susceptbility of Polyakov loop for SU(3) 1307.5958 Lo et al

28

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