An Overabundance of X-ray Binaries Near the Galactic Center

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Presentation transcript:

An Overabundance of X-ray Binaries Near the Galactic Center Michael Muno (UCLA) with Fred Baganoff (MIT), Eric Pfahl (UVa), Mark Morris, Andrea Ghez, Jessica Lu (UCLA), Geoff Bower (Berkeley), Farhad Yusef-Zadeh, and Doug Roberts (Northestern)

Five Years of Chandra Observations of the Galactic Center To search for rare objects, such as accreting black holes and neutron stars. How does accretion occur at low rates? To understand how the central 4 106 solar-mass black hole (Sgr A*) grows. Why is Sgr A* accreting at such a low rate? Does stellar dynamics feed stars into Sgr A*? How did dozens of young, massive stars come to lie within 1 pc of Sgr A*?

Five Years of Chandra Observations of the Galactic Center Sgr A* 5 pc

X-rays from Accreting Compact Objects Image creates with binsim, by Rob Hynes Location of Compact Object One Solar Radius Most of the X-ray sources are accreting white dwarfs, the brightest 10% of which are detectable. Accreting neutron stars and black holes are 100 times rarer, and most are accreting at low rates.

Searching for Accreting Compact Objects Sources that produce sudden, bright outbursts are likely to be accreting black holes and neutron stars. We found 7 such transients within 25 pc of the Galactic center. Sgr A* 5 pc

Searching for Accreting Compact Objects Sources that produce sudden, bright outbursts are likely to be accreting black holes and neutron stars. We found 7 such transients within 25 pc of the Galactic center. New Transient Sgr A* 5 pc

One Low-Mass X-ray Binary The X-ray light curve displays partial eclipses at the 8 hour orbital period. Infrared images reveal no infrared companion with K<15, ruling out a high-mass star. Muno et al. (2005b)

An Overabundance of X-ray Binaries in the Central Parsec 4 of 7 transients are within 1 pc of the Galactic Center. The chance of this happening randomly is less than 1 in 5000. Sgr A* 1 pc

Young High-Mass X-ray Binaries Seven Myr ago, several dozen massive stars formed from in a 104 Msun burst. Up to 300 black holes may have already descended from these stars. Up to 10% of these could be in HMXBs, or on order 30 systems. Sgr A* 1 pc Infrared laser guide-star image courtesy W.M. Keck Observatory. Muno et al. (2005a)

Dynamically Forming LMXBs 1 pc 47 Tuc rc = 6 104 Mo pc-3 s = 12 km s-1 rc = 7 106 Mo pc-3 s = 70 km s-1 Grindlay et al. 2001; Pooley et al. 2003

LMXBs Form When Black Holes Capture Stars 104 black holes have dynamically settled into the central pc (Morris 1993, Miralda-Escudé & Gould 2000). Pfahl & Loeb (in prep.) estimate that these form LMXBs via binary-single interactions at a rate of 10-6 yr -1. Over the dynamical time scale of 10 Gyr, 103 LMXBs could form. simulation by E. Pfahl (Uva) Muno et al. (2005)

Summary A faint radio and X-ray transient provides the most direct evidence yet that accreting black holes release about half of their energy as jets. This is also suspected to explain why Sgr A* appears so faint in X-rays. Transient X-ray binaries are overabundant within 1 pc of Sgr A*. This suggests that a cusp of compact objects surrounds it, which would prevent low-mass stars from remaining in the region.