Ji-Ming Shi, Julian H. Krolik, Stephen H. Lubow, John F. Hawley
We present the first three-dimensional magnetohydrodynamic (MHD) simulations
of a circumbinary disk surrounding an equal mass binary. The binary maintains a
fixed circular orbit of separation $a$. As in previous hydrodynamical
simulations, strong torques by the binary can maintain a gap of radius $\simeq
2a$. Streams curve inward from $r \simeq 2a$ toward the binary; some of their
mass passes through the inner boundary, while the remainder swings back out to
the disk. However, we also find that near its inner edge the disk develops both
a strong $m=1$ asymmetry and growing orbital eccentricity. Because the MHD
stresses introduce more matter into the gap, the total torque per unit disk
mass is $\simeq 14$ times larger than found previously. The inner boundary
accretion rate per unit disk mass is $\simeq 40$ times greater than found from
previous hydrodynamical calculations. The implied binary shrinkage rate is
determined by a balance between the rate at which the binary gains angular
momentum by accretion and loses it by gravitational torque. The large accretion
rate brings these two rates nearly into balance, but in net, we find that $\dot
a/a < 0$, and its magnitude is about 2.7 times larger than predicted by the
earlier hydrodynamic simulations. If the binary comprises two massive black
holes, the accretion rate may be great enough for one or both to be AGN, with
consequences for the physical state of the gas both in the disk body and in its
inner gap.
View original:
http://arxiv.org/abs/1110.4866
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