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Joshua Faber (NSF AAPF Fellow, UIUC) Stu Shapiro (UIUC) Keisuke Taniguchi (UIUC) Thomas Baumgarte (Bowdoin) Fred Rasio (Northwestern) Paper Submitted to PRD. Relativistic Dynamical Calculations of Merging Black Hole-Neutron Star Binaries. Merging BH-NS binaries.
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Joshua Faber (NSF AAPF Fellow, UIUC) Stu Shapiro (UIUC) Keisuke Taniguchi (UIUC) Thomas Baumgarte (Bowdoin) Fred Rasio (Northwestern) Paper Submitted to PRD Relativistic Dynamical Calculations of Merging Black Hole-Neutron Star Binaries
Merging BH-NS binaries • Relativistic binaries projected to be a primary source of GW detections • GRB050509b may be located 35kpc from center of elliptical with low SFR -> binary compact object merger • More massive than NS-NS-> seen at greater distance (10-100/yr for LIGO II; Belczynski et al. 2002, Voss+Tauris2003) • May shed light on internal structure of NS, behavior of matter at high density • Violent disruption process exposes interior of NS for study • Links to GRB observations • Unclear whether they are a source of r-process elements
BHNS binaries: numerical issues • Only (Quasi-)Newtonian BH-NS dynamical calculations so far (Lee+Kluzniak, Janka et al., Rosswog et al.) • NSs are not Newtonian objects and require a hydrodynamic treatment • Self-gravity is important during tidal disruption • BHs do not exist in Newtonian or PN physics • Moving BHs require careful treatment of the singularity • More difficult than NSNS mergers; more difficult than BHBH, too?
Description of method • We assume an extreme mass ratio (Baumgarte et al.) • MBH>>MNS -> BH is fixed in place • Conformally Flat gravity (Isenberg; Wilson+Mathews): • GR minus 1 d.o.f. • Exact for spherically symmetric systems (Schwarzschild) • Einstein's Equations reduce to 5 linked non-linear elliptic eqs. • NS: Polytropic EOS, corotating • Low-compactness models from BSS -> disruption occurs outside the ISCO for larger mass ratios • Adiabatic evolution
Our hydrodynamical code • Smoothed Particle Hyrdodynamics (SPH) used to describe NS • ~100,000 particles • Field equations are solved using LORENE, a multi-domain, spheroidal, spectral methods solver • Solve for NS gravitational field in BH background • Similar to NSNS code of Faber, Grandclément and Rasio (2004)
Equilibrium configurations • Relaxed relativistic equilibrium BH-NS configurations • Initial conditions satisfy integrated Euler equation to <.001 • Derived from CF version of BSS • Future results from TBFS • Very nearly Keplerian
The stability of mass transfer • Stable vs. unstable mass transfer: • mass transfer should increase binary separation • Does NS shrink within its Roche Lobe? • Unstable: Immediate disruption • Stable: Periodic mass transfer?
Unstable mass transfer • Expected for soft EOS (e.g., Γ=1.5) • Rapid disruption • Much more dynamical than QE mass transfer description
“Stable” mass transfer • Not stable: GW losses drive mass loss instability • Periodic mass transfer can occur, since mass loss inward -> increase in binary separation
Evolution of mass loss and binary separation • Mass loss regulates the binary separation • Remnant develops orbital eccentricity • Orbital parameters evolve continuously • We overestimate mass loss outward
Conclusions • No stable mass transfer for BHNS binaries • Mass transfer plays important role in determining binary separation on dynamical timescale • Possibility of efficiently transferring angular momentum outward • GRB progenitor? • Future work: irrotational NS, physical compaction, AV • Drop extreme mass ratio limit • Eventually move BH into grid