GCN Circular 236
Subject
On the Lensing Interpretation of GRB 990123
Date
1999-01-28T10:49:17Z (25 years ago)
From
Shude Mao at MPI,Garching <smao@ibm-2.MPA-Garching.MPG.DE>
Shude Mao (Max Planck Inst. for Astrophysics) reports:
Djorgovski et al. (GCN Circ. 216) suggested that GRB 990123 might be
highly magnified (A>10) by an intervening galaxy based on a variety of
arguments. A likely scenario is that the bursting source is very close to
a fold caustic. As a result, we have a PAIR of highly magnified images
(we call B2 and B3) plus other additional image(s).
If this scenario is correct, then from the lensing theory, three points
can be immediately made:
1. There must be a fainter burst that has arrived before GRB 990123. This
first burst (we call B1) would be offset from GRB 990123 by about ~2".
This expectation is valid no matter what the lens potential.
Notice that, in this scenario, all the optical and radio afterglows
we see now are the sum of the first-arriving burst B1 and GRB 990123.
High resolution imaging in the radio and in the optical (with HST)
may reveal the presence of B1.
The time interval and intensity ratio between B1
and GRB 990123 does depend on the model. A rough estimate
of the time delay is a few days to a month, and the intensity
ratio is around a few to a few tens. These predictions can be made
more precise when the astrometries and velocity dispersion of the
foreground galaxy are better known. The gamma-ray burst data archive
should be searched to see whether there was such a burst. A fourth
image (B4) much fainter than GRB 990123 may also appear after about a month.
2. The gamma-ray burst host galaxy, since it is extended, will be distorted
into a ring or arcs if the center of the host galaxy does not have
a significant offset from GRB 990123. Such features can be detected with
HST imaging (see also Turner, GCN 221). This expectation is independent
of the models.
3. The close pair of images should have roughly equal intensities.
The time delay between these two images depends strongly
on the magnification; a simple model shows that it can be between
tens of seconds to a fraction of a day. This close pair therefore
should have ALREADY left imprints on the after glow light curves.
The close pair should have an image splitting of about 0.05" to a
fraction of arcsecond; HST imaging will either provide a confirmation
or rule out this scenario.
If the time delay between the close pair can be as short as tens
of seconds, this raises an intriguing possibility: is GRB 990123
itself lensed? That is, GRB 990123 may be superposed by two bursts
coming from the close pair. These two bursts have a time lag
of about 15 seconds, producing the first and second peaks in
the light curve. It will be very interesting to check whether
the gamma-ray spectrum and light curve of GRB 990123 are consistent
with this superposition scenario. If this hypothesis is correct, then
the close pair should have an imaging splitting of ~0.05" and
each is magnified by a factor of about 100.
More information (including figures) can be found at
http://www.mpa-garching.mpg.de/~smao/grb.html
This report may be cited.
[GCN OP NOTE: This Circular was received at 09:19 UT, but was delayed until
an entry in the distribution list was created.]