1 / 23

【 May . 20th. 2009. CS QCD II】

【 May . 20th. 2009. CS QCD II】. The pasta structure of quark-hadron phase transition and the effects on magnetised compact objects. N. Yasutake (NAOJ) 安武 伸俊. ・ Introduction A. Finite size effects on the quark-hadron phase transition ( NY , Maruyama, Tatsumi in prep . )

saxon
Télécharger la présentation

【 May . 20th. 2009. CS QCD II】

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. 【 May. 20th. 2009. CS QCD II】 The pasta structure of quark-hadron phase transition and the effects on magnetised compact objects N. Yasutake (NAOJ) 安武 伸俊 ・Introduction A. Finite size effects on the quark-hadron phase transition (NY, Maruyama, Tatsumi in prep.) B. Rotating compact stars w/wo magnetic field (NY, Hashimoto, Eriguchi, 2005 PTP; NY, Kiuchi, Kotake, 2009 MNRAS submitted, etc…) C. Chiral symmetry restoration in proto-neutron stars (NY & Kashiwa 2009 PRD) ・Summary

  2. “HOT TPICS IN QUARK NUCLEAR PHYSICS” 4.3km “numerical experiment” “experiment” Lattice QCD (KEK:IBM Blue Gene) “effective theory” Y. Nambu (1921~now) 2008 Nobel Prize ・100m below ground ・The LHC has started !!  STOP…!? “Others” Ads/CFT correspondence …

  3. Compact stars topics • Supernova remnants • Non-spherical effects are fundamentally important for SN mechanism !!  “rotation” and “magnetic field” 3D simulation of SN (Iwakami et al. 2008) • Magnetars (B~1014G at surface) • Origin ? • What kind of matter in the core ?  Structure ? Our study is “ Magnetized Rotating compact stars w/wo exotic matter”

  4. A. Finite size effects on the quark-hadron phase transition cf. Maruyama et al., PRD 2007 (T=0) NY, Maruyama, Tatsumi, in prep. (T≠0)

  5. Pasta Structure • In the mixed phase of 1st order phase transitions, non-uniform “Pasta” structure is expected. These structures will appear at ① Liquid-gas : supernova matter ② Neutron drip: neutron star inner crust ③ Meson condensation: neutron star outer core ④ Quark-hadron: neutron star inner core (Hybrid star)  Today’s Talk

  6. Quasi-chemical representation(“chemical picture”) Iosilevskiy et al. Non-ideal U–O plasma “Strange” stars O UO3 U UO2 U+ u, d, s, p, n, e mu, md, ms, mp, mn, me UO O- u + e  d d  s p + e  n n  u + 2d (p  2u + d) Multi-molecular model (Liquid & Gas) U + O + O2 +UO +UO2 + UO3 U+ + UO+ +UO2+ + O− + UO3− + e− U + 2O  UO2 2O  O2 U+ + e  U UO3 + e  UO3– . . . . . . mU + 2mU= mUO2 2mO =mO2 mU+ + me= mU mUO3 + me= mUO3– . . . . . . . . . . . . . 

  7. EOSs ①: MIT bag model and BHF hadron EOS Maruyama et al. (2007)PRD 76, 123015 Hadron phase: Brueckner Hartree Fock (Baldo et al.(1999), with hyperons) + Quark phase: MIT model (Free fermions - bag constant) For mixed phase ・Balance of “Coulomb interaction” and “Surface tension” ・Electrical charge neutrality ・Baryon number conservation ・Phase equilibrium

  8. EOSs ②:Uncertainty for surface tension • Theoretical estimation on the MIT bag model for strangelets (Farhi & Jaffe 1984; Berger & Jaffe 1987) • Lattice gauge simulations at finite temperature (Kajantie et al. 1991; Huang et al. 1990, 1991) σ= 10 – 100 MeV/fm2 • However,for σ> 40 MeV/fm2, EOSs are almost same as ones under Maxwell construction (Maruyama et al. 2007). We choose σ= 10, 40 MeV/fm2

  9. EOSs ③: Brueckner Hartree Fock (Baldo et al.(1999), w/wo hyperon) BHF(with hyperon) QH pasta (σ=10 MeV/fm2) QH pasta (σ=40 MeV/fm2) BHF(without hyperon) HARD EOS • ① Number of hyperons are suppressed by appearance of quark matter. • EOS becomes harder than only hyperon case. • ② For strong surface tension • EOS becomes 1st phase transition like (Maxwell condition-like). • We expand them to “finite temperature” cases. Qaurk-Hadron pasta EOSs “Droplet” does not appears. “Rod” does not appears.

  10. EOS with Quark-Hadron pasta at finite temperature (T=30 MeV, Yl=0) QM QM Mixed HM Mixed HM • finite T  more Maxwel-like EOS • Softer EOS region in mixed phase

  11. B. Rotating compact stars w/wo magnetic field cf. NY, Hashimoto, Eriguchi, PTP 2005 NY, Kiuchi, Kotake, MNRAS 2009 submitted

  12. Magnetized rotating star equilibrium Unfortunately, there is not the formulation for 【 Full GR, toroidal + poloidal magnetic field, rotation 】 ! ! 【 Full GR, rotation 】 +  【 Quark Matter 】 NY, Hashimoto, Eriguchi (2005) 【 Full GR, toroidal magnetic field, rotation 】 + 【 Quark Matter 】 NY, Kiuchi, Kotake (2009), submitted Assumptions 1. stationary, aximetric star 2. perfect fluid, infinite conductivity 3. no meridional flow 4. barotropic EOS

  13. Neutron Stars with hyperons ρ0 BΦ M =1.31 Ms Bmax=7.1×1017G Neutron Stars without hyperons M0=1.45Ms, Φ=5×1029G cm2 ρ0 BΦ M =1.32 Ms Bmax=4.6×1017G

  14. Hybrid Star : B=100 MeV/fm3, σ=10 MeV/fm2 ρ0 BΦ M =1.30 Ms Bmax=6.2×1017G Hybrid Star : B=100 MeV/fm3, σ=40 MeV/fm2 M0=1.45Ms, Φ=5×1029G cm2 ρ0 BΦ M =1.31 Ms Bmax=6.2×1017G

  15. Density distributions for equatorial direction Mixed Phase

  16. C. Chiral symmetry restoration in proto-neutron stars cf. “Lepton effects on the proto-neutron stars with the hadron-quark mixed phase in the Nambu-Jona-Lasinio model” NY, Kashiwa, PRD 2009

  17. 3-flavor NJL model ①(only chiral phase transitions) Gv・・・ vectorcoupling constant  parameter λ・・・ Gelll-Mann matrix

  18. EOS and Chiral symmetry restoration • High Yl  High Ye  low ns • chiral restoration of s-quark is suppressed • Hard EOS !! Quark (SU(3) NJL) • High Yl  High Ye  low nn • repulsive nuclear force is suppressed • Soft EOS !! Hadron (Shen et al.1998)

  19. Quark-Hadron phase transition bulk Gibbs construction Maxwell construction large surface tension small surface tension “finite size effects”

  20. Hybrid (bulk Gibbs) M-nBC relations Hadron (Shen et al.1998) Hybrid (Maxwell) <Without the phase transition> Ejection of leptons  The EOS becomes HARD !! • <With the phase transition> • Ejection of leptons • The EOSs become SOFT !!

  21. Summary & Discussion

  22. Summary & Discussion A: “Pasta structures on the quark-hadron phase transition” ① Number of hyperons are suppressed by appearance of quark matter. • EOS becomes harder than only hyperon case. • ② Strong surface tension • EOS becomes Maxwell condition-like. • ③ Finite temperaturecases. • EOS becomes more Maxwell condition-like. • B: “Structures of magnetars with QH pasta” • Clearly, distributions of magnetic field are different between w/wo phase transition. • Strong magnetic field may change EOSs ? • Poloidal magnetic field? Other origins of magnetic field? • Astrophysical phenomena? (SN, GRB, NS cooling curve/spin-down rate)

  23. C: “The Chiral restoration on the structures of proto-compact stars” • With PT : small Yl  soft EOS • Without PT: small Yl  hard EOS • This will change dynamics of SN, GRB. • How about color super conductivity? D: “Other topics” • Gravitational wave ? [NY et al. 2007, etc. ] • NS+NS, NS+BH binaries • Neutrino emission ? [Fischer et al. 2008, etc.] 謝謝!

More Related