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Radiation Recoil Velocity of a Neutron Star Y. Kojima Hiroshima Univ. JGRG20 at Kyoto Sept. 21-25 in 2010 The 20 th Anniversary of JGRG & The 60 th Birthday.

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Presentation on theme: "Radiation Recoil Velocity of a Neutron Star Y. Kojima Hiroshima Univ. JGRG20 at Kyoto Sept. 21-25 in 2010 The 20 th Anniversary of JGRG & The 60 th Birthday."— Presentation transcript:

1 Radiation Recoil Velocity of a Neutron Star Y. Kojima Hiroshima Univ. JGRG20 at Kyoto Sept. 21-25 in 2010 The 20 th Anniversary of JGRG & The 60 th Birthday of Prof. Nakamura & Prof. Maeda

2 Contents High velocity of BH/NSs as a consequence of violent event Comment on high velocity of BH by GW radiation Models + recent observation Proper motion of pulsars/magnetars Magnetic fields? Recoil velocity of a pulsar by EM radiation Shifted dipole Model ( Harrison &Tademaru 1975) Model of magnetic dipole + quadrupole radiation (Y.K & Y. Kato 2010) Discussion

3 Runaway Black Hole by GW Velocity by linear momentum radiation reaction Quadrupole +Octapole Gravitational Radiation Bekenstein 1973 -… BH Perturbation 1983 - … Nakamura+Haugan+Sasaki+Oohara+Y.K.+…. Numerical Relativity 2006 -… Baker et al …, Campanelli et al, +… Maximum velocity, ‘anti-kick’,…

4 Observational Evidence for High Velocity of BHs ? e.g., Quasar E1821+643 @z=0.297 2100km/s Robinson et al 2010 SDSS J1054.35+345631.3 @z=0.272 3500km/s Shields et al 2009 For super massive BH, GW recoil? For stellar mass BH, some ambiguity with SN

5 Proper Motion of PSRs Proper motion by PSR timing methods,interferometers Helfand, Taylor & Manchester (1977) for 5 PSRs Hobbs et al (2005) for 233 PSRs

6 Velocity of PSR/Magnetars Proper motion Hobbs et al (2005) Mean 3D velocity is 400km/s Fast moving pulsars PSR2224+45(Cordes+1993) B1508+55(Chatterjee+2005) Upper limits for magnetars AXP XTEJ1810-197 1E2259+586 SGR 1900+14 (Helfand+2007, Kaplan+ 2009…)

7 Kick Velocity of Pulsars Proposed Mechanisms ( No References) Pre-natal scenario Collapse of binary Natal scenario Asymmetry of SN explosion Neutrinos/(Magneto-) Hydrodynamical waves Post-natal scenario EM radiation and its recoil Magnetic fields

8 Kick Velocity caused by Magnetic Fields Asymmetry of SN explosion Neutrinos/(Magneto-) Hydrodynamical waves Strong field strength EM-radiation and its recoil Field configuration When and how is the (strong) magnetic field generated? Fossil or dynamo? Upper limit for magnetars means no importance? Complicated?

9 Strength & configuration of magnetic fields in newborn NS Strong magnetic fields generated by dynamo

10 Global Simulation of Dynamo for Fully Convective Rotating Stars Saturated at W. Dobler et. al., (2006) ApJ368, 336 NOT Neutron Star Higher multipoles are generated.

11 Strength & configuration of magnetic fields in newborn NS Strong magnetic fields generated by dynamo (Thompson & Duncan 1993 Bonanno, Urpin & Belvedere 2006) For a fast rotator, strong ordered fields are generated. Maximum strength decreases, and higher mulitipole (small scale) fields dominate with decrease of initial spin. Almost dipole field in manetars, but dipole field + higher mulitipoles in PSRs

12 Recoil Velocity by Radiation Radiation of (GW/EM) waves Energy is an incoherent sum In linear momentum radiation, interference is important Strength Configuration

13 Dipole shifted from center by s Nonzero momentum by up-down asymmetry of B Off-center Dipole Model Harrison &Tademaru (1975)ApJ 201, 447 ( Lai et al (2001) ApJ 549, 1111 ) Quadrupole moment ? Much larger Q

14 Dipole and Quarupole Radiation Large quadrupole moment But, weak constraint in present slow rotating phase Spindown is given by

15 Model of Dipole plus Quradrupole Radiation  Paramters Strength Configuration  Magnetic radiation M(l,m) M(1,1), M(2,1),M(2,2)  Off-center Dipole M(1,1),M(2,1),E(1,1)

16 Pure Dipole Dipole + Quadrupole Global Structure of Closed Field Lines near Light Cylinder

17 Symmetry of Radiation Partern Poynting flux +z -z Symmteric Asymmteric Kick

18 Radiation Loss and Evolution Energy loss determines the spin evolution. Momentum loss determines the acceleration. Kinetic velocity is given by M(1,1)M(2,1)M(2,2) M(1,1) x M(2,1)

19 Efficient Configuration  Large momentum radiation Orthogonal dipole and quadrupole planes  Small M(2,2) radiation Small inclination angle Almost axially symmetric quadrupole field  Maximum velocity at

20 Summary Kick velocity by rotating magnetic dipole and quadrupole moments Strong field is NOT necessary Configuration is important  Slow velocity of magnetar with almost diople  High velocity of PSR with large quadrupole Or magnetic field is not relevant?

21 Final Remaks Porper motion is a relic of violent event Direct observation by GWs, GRBs LCGT soon! We hope better understanding of the relativistic astrophysics by the next anniversary of JGRG meeting

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