What we know about gamma-ray bursts
How they look as functions of time and energy
Perhaps the most striking feature of the time profiles of gamma-ray bursts
is the diversity of their time structures. Some burst light curves are spiky
with large fluctuations on all time scales, while others show rather simple
structures with few peaks. However, some bursts are seen with both
characteristics present within the same burst! In a few cases, burst sources
have repeated their appearance. However, no persistent, strictly periodic
behavior has been seen from gamma-ray bursts.
The durations of gamma-ray bursts range from about 30 ms to over 1000 s.
However, the duration of a gamma-ray burst is difficult to quantify since it
is dependent upon the sensitivity and the time resolution of the experiment
which observes the event. The "tip of the iceberg" effect tends to
cause weaker bursts to be observed as shorter, since only the higher parts of
the peak emission are observable.
A unique feature of gamma-ray bursts is their high-energy emission: almost
all of the power is emitted above 50 keV. Simultaneous soft X-ray emission has
been seen in a few cases, with the power in the soft X-rays being only a few
percent of the power found in the gamma-ray region. The energy spectra can
usually be fitted by an optically thin bremsstrahlung-like shape, although
other shapes can be used.
How they are distributed in the sky and how bright they are
The most direct evidence of the 3-D spatial distribution of the sources of
gamma-ray bursts comes from the observed intensity and sky distributions. The
angular (sky) distribution provides two of the dimensions of the spatial
distribution, while the intensity distribution is a convolution of the unknown
luminosity function and the radial distribution. Even though the luminosity
function is unknown, the intensity distribution can still provide constraints
on the allowable spatial distributions of gamma-ray burst sources.
Can we at least tell how far away gamma-ray bursts are? Actually, no, not
with any certainty. From the early 1970s it has been apparent that gamma-ray
bursts come from all parts of the sky with approximately equal probability.
Since other aspects of gamma-ray bursts (such as the fast rise time
[<1 ms in some cases] and high photon energies) seemed consistent with a
neutron star origin, most people prior to 1991 believed that gamma-ray bursts
came from galactic neutron stars, and that instruments simply hadn't had the
sensitivity to probe deeply enough to see a bias towards the galactic center
and plane. However, since 1991 the Burst and Transient Source Experiment
(BATSE) aboard the
Compton Gamma-Ray
Observatory has seen nearly one gamma-ray burst per day, and these too are
nearly isotropic
(click for the sky
map of the first 921 bursts or here for a
movie of the first few hundred bursts). It is believed that, if galactic
neutron stars really are the sources of gamma-ray bursts, BATSE should be able
to see them far enough away that the distribution should be more like a
pancake than a sphere. Another piece of evidence comes from the number of
sources seen with at least a given flux. If the universe were Euclidean and
the sources were spread out uniformly, then out to a distance r there would be
a number of sources proportional to r3, and the dimmest sources
would have fluxes proportional to 1/r2. Thus, in a Euclidean
universe with uniformly distributed sources of a given intrinsic luminosity, a
plot of log N (N=number of sources at a flux greater than S) versus log S
should have a slope of -3/2. At the highest fluxes this slope is seen, but at
lower fluxes the slope becomes smaller, exhibiting a continuous rollover and
becoming about -0.8 at the lowest fluxes BATSE can see.
What does that mean? The dropoff at lower fluxes, which corresponds to
greater distances if the intrinsic luminosity is constant, means that in some
sense there is an edge to the distribution. For example, if the sources were
distributed in a thin plane instead of a sphere, the slope would be -1, and for
sources in a line the slope is -0.5. Even if the source distribution is
spherical, the slope will roll over if the sources become less dense at greater
distances, or if the flux drops off faster than 1/r2. Because of the
isotropy of the distribution, many people believe that gamma-ray bursts are
cosmological, at typical
redshifts z=1,
where the redshift would decrease the flux in about the right way to account
for the log N - log S rollover.
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