SIMBAD references

The only microlensing events toward the Magellanic Clouds for which the location of the lens is strongly constrained are the two binary caustic crossing events. In at least one and possibly both cases, the lens lies at or close to the Magellanic Clouds themselves. On the face of it, this seems an improbable occurrence if the Galactic dark halo provides the bulk of the lensing population, as suggested by standard analyses of the MACHO data set toward the Large Magellanic Cloud (LMC). We use a binomial statistic to assess the prior probability of observing M nonhalo binary caustic events given a total sample of N caustic binaries. We generalize for the case of multicomponent Galactic and Magellanic Cloud models the Bayesian likelihood method for determining the lens mass and halo fraction from the observed timescales. We introduce a new statistic, the ``outcome discriminator'', which measures the consistency between the binary caustic data, prior expectation, and the MACHO two-year LMC data set as a whole. If the Magellanic Clouds are not embedded in their own dark halos of MACHOs, then the discovery of two nonhalo caustic binary events out of two (M=N=2) is inconsistent with expectation given the MACHO data set. Galactic models in which M=1 is the likeliest outcome are also inconsistent with the data, although models in which M=1 has a reasonable prior probability are not. We consider the possibilities that the Magellanic Clouds are embedded in dark haloes of their own or that the Galactic halo is intrinsically deficient in the binary systems that produce caustic crossing events. Either of these possibilities provide greater compatibility between observation and prior expectation, although the idea of Magellanic haloes is perhaps the more natural of the two and has support from kinematical studies.