77 research outputs found
Black Hole-Neutron Star Mergers in Globular Clusters
We model the formation of black hole-neutron star (BH-NS) binaries via
dynamical interactions in globular clusters. We find that in dense, massive
clusters, 16-61% of the BH-NS binaries formed by interactions with existing BH
binaries will undergo mergers driven by the emission of gravitational
radiation. If the BHs are retained by the cluster after merging with a NS, the
BHs acquire subsequent NS companions and undergo several mergers. Thus, the
merger rate depends critically upon whether or not the BH is retained by the
cluster after the merger. Results from numerical relativity suggest that kick
imparted to a ~7 M_sun BH after it merges with a NS will greatly exceed the
cluster's escape velocity. In this case, the models suggest that the majority
of BH-NS mergers in globular clusters occur within 4 Gyrs of the cluster's
formation and would be unobservable by Advanced LIGO. For more massive BHs, on
the other hand, the post merger kick is suppressed and the BH is retained.
Models with 35 M_sun BHs predict Advanced LIGO detection rates in the range
0.04 - 0.7 per year. On the pessimistic end of this range, BH-NS mergers
resulting from binary-single star interactions in globular clusters could
account for an interesting fraction of all BH-NS mergers. On the optimistic
end, this channel may dominate the rate of detectable BH-NS mergers.Comment: 13 pages, 7 figures, 3 tabels, accepted for publication in MNRA
Dynamically formed black hole+millisecond pulsar binaries in globular clusters
The discovery of a binary comprising a black hole (BH) and a millisecond
pulsar (MSP) would yield insights into stellar evolution and facilitate
exquisitely sensitive tests of general relativity. Globular clusters (GCs) are
known to harbor large MSP populations and recent studies suggest that GCs may
also retain a substantial population of stellar mass BHs. We modeled the
formation of BH+MSP binaries in GCs through exchange interactions between
binary and single stars. We found that in dense, massive clusters most of the
dynamically formed BH+MSP binaries will have orbital periods of 2 to 10 days,
regardless of the mass of the BH, the number of BHs retained by the cluster,
and the nature of the GC's binary population. The size of the BH+MSP population
is sensitive to several uncertain parameters, including the BH mass function,
the BH retention fraction, and the binary fraction in GCs. Based on our models,
we estimate that there are dynamically formed BH+MSP binaries in
the Milky Way GC system, and place an upper limit on the size of this
population of . Interestingly, we find that BH+MSP binaries will be
rare even if GCs retain large BH populations.Comment: 15 pages, 5 figures, 2 tables, accepted for publication in MNRAS,
updated to match published versio
Low-mass X-ray binaries from black-hole retaining globular clusters
Recent studies suggest that globular clusters (GCs) may retain a substantial
population of stellar-mass black holes (BHs), in contrast to the long-held
belief of a few to zero BHs. We model the population of BH low-mass X-ray
binaries (BH-LMXBs), an ideal observable proxy for elusive single BHs, produced
from a representative group of Milky Way GCs with variable BH populations. We
simulate the formation of BH-binaries in GCs through exchange interactions
between binary and single stars in the company of tens to hundreds of BHs.
Additionally, we consider the impact of the BH population on the rate of
compact binaries undergoing gravitational wave driven mergers. The
characteristics of the BH-LMXB population and binary properties are sensitive
to the GCs structural parameters as well as its unobservable BH population. We
find that GCs retaining BHs produce a galactic population of ejected BH-LMXBs whereas GCs retaining only BHs produce zero
ejected BH-LMXBs. Moreover, we explore the possibility that some of the
presently known BH-LMXBs might have originated in GCs and identify five
candidate systems.Comment: 27 pages, 18 figures, 7 tables, submitted to MNRA
The Black Hole Formation Probability
A longstanding question in stellar evolution is which massive stars produce
black holes (BHs) rather than neutron stars (NSs) upon death. It has been
common practice to assume that a given zero-age main sequence (ZAMS) mass star (and perhaps a given metallicity) simply produces either an NS or a BH, but this fails to account for a myriad of other variables that may effect this outcome, such as spin, binarity, or even stochastic differences in the stellar structure near core collapse. We argue that instead a probabilistic description of NS versus BH formation may be better suited to account for the current uncertainties in understanding how massive stars die. We present an initial exploration of the probability that a star will make a BH as a function of its ZAMS mass, P_(BH)(M_(ZAMS)). Although we find that it is difficult to derive a unique P_(BH)(M_(ZAMS)) using current measurements of both the BH mass distribution and the degree of chemical enrichment by massive stars, we demonstrate how P_(BH)(M_(ZAMS)) changes with these various observational and theoretical uncertainties. We anticipate that future studies of Galactic BHs and theoretical studies of core collapse will refine P_(BH)(M_(ZAMS)) and argue that this framework is an important new step toward better understanding BH formation. A probabilistic description of BH formation will be useful as input for future population synthesis studies that are interested in the formation of X-ray binaries, the nature and event rate of gravitational wave sources, and answering questions about chemical enrichment
Population Synthesis of Hot Subdwarfs: A Parameter Study
Binaries that contain a hot subdwarf (sdB) star and a main sequence companion
may have interacted in the past. This binary population has historically helped
determine our understanding of binary stellar evolution. We have computed a
grid of binary population synthesis models using different assumptions about
the minimum core mass for helium ignition, the envelope binding energy, the
common envelope ejection efficiency, the amount of mass and angular momentum
lost during stable mass transfer, and the criteria for stable mass transfer on
the red giant branch and in the Hertzsprung gap. These parameters separately
and together can significantly change the entire predicted population of sdBs.
Nonetheless, several different parameter sets can reproduce the observed
subpopulation of sdB + white dwarf and sdB + M dwarf binaries, which has been
used to constrain these parameters in previous studies. The period distribution
of sdB + early F dwarf binaries offers a better test of different mass transfer
scenarios for stars that fill their Roche lobes on the red giant branch.Comment: 21 pages, 15 figures, accepted for publication in Ap
Light Curves of Core-Collapse Supernovae with Substantial Mass Loss using the New Open-Source SuperNova Explosion Code (SNEC)
We present the SuperNova Explosion Code (SNEC), an open-source Lagrangian code for the hydrodynamics
and equilibrium-diffusion radiation transport in the expanding envelopes of supernovae. Given a model of a
progenitor star, an explosion energy, and an amount and distribution of radioactive nickel, SNEC generates the
bolometric light curve, as well as the light curves in different wavelength bands assuming black body emission.
As a first application of SNEC, we consider the explosions of a grid of 15 M_⊙ (at zero-age main sequence)
stars whose hydrogen envelopes are stripped to different extents and at different points in their evolution. The
resulting light curves exhibit plateaus with durations of ∼20 − 100 days if & 1.5 − 2 M_⊙ of hydrogen-rich
material is left and no plateau if less hydrogen-rich material is left. The shorter plateau lengths are unlike the
Type IIP supernova light curves typically observed in nature. This suggests that, at least for zero-age main
sequence masses . 20 M_⊙, hydrogen mass loss occurs as an all or nothing process, perhaps pointing to the
important role binary interactions play in observed mass-stripped supernovae (i.e., Type Ib/c events). These
light curves are also unlike what is typically seen for Type IIL supernovae, arguing that simply varying the
amount of mass loss cannot explain these events. The most stripped models begin to show double-peaked light
curves similar to what is often seen for Type IIb supernovae, confirming previous work that these supernovae
can come from progenitors that have a small amount of hydrogen and a radius of ∼ 500 R_⊙
Probing Intermediate Mass Black Holes With Optical Emission Lines from Tidally Disrupted White Dwarfs
We calculate the emission line spectrum produced by the debris released when
a white dwarf (WD) is tidally disrupted by an intermediate-mass black hole
(IMBH; M\sim 10^{2}-10^{5}\msun) and we explore the possibility of using the
emission lines to identify such events and constrain the properties of the
IMBH. To this end, we adopt and adapt the techniques developed by Strubbe &
Quataert to study the optical emission lines produced when a main sequence (MS)
star is tidally disrupted by a supermassive black hole. WDs are tidally
disrupted outside of the event horizon of a < 10^{5}\msun black hole, which
makes these tidal disruption events good signposts of IMBHs. We focus on the
optical and UV emission lines produced when the accretion flare photoionizes
the stream of debris that remains unbound during the disruption. We find that
the spectrum is dominated by lines due to ions of C and O, the strongest of
which are \ion{C}{4} 1549 at early times and [\ion{O}{3}]
5007 at later times. Furthermore, we model the profile of the emission
lines in the [\ion{O}{3}] 4959, 5007 doublet and find that it
is highly asymmetric with velocity widths of up to , depending on the properties of the WD-IMBH system and the
orientation of the observer. Finally, we compare the models with observations
of X-ray flares and optical emission lines in the cores of globular clusters
and propose how future observations can test if these features are due to a WD
that has been tidally disrupted by an IMBH.Comment: 19 pages, 9 figures, accepted for publication in The Astrophysical
Journa
Luminous [O III] and [N II] from Tidally Disrupted Horizontal Branch Stars
We model the emission lines generated in the photoionised debris of a tidally
disrupted horizontal branch star. We find that at late times, the brightest
optical emission lines are [N II] \lambda\lambda 6548,6583 and [O III]
\lambda\lambda 4959,5007. Models of a red clump horizontal branch star
undergoing mild disruption by a massive (50 -- 100 M_\sun) black hole yield an
emission line spectrum that is in good agreement with that observed in the NGC
1399 globular cluster hosting the ultraluminous X-ray source CXOJ033831.8 -
352604. We make predictions for the UV emission line spectrum that can verify
the tidal disruption scenario and constrain the mass of the BH.Comment: 8 pages, 6 figures, Accepted for publication in MNRA
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