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May 18, 1999: Eyes in the Southern Hemisphere are turning to capture the fading glory of a gamma-ray burst that appeared on May 10. The Burst and Transient Source Experiment (BATSE) aboard the Compton Gamma Ray Observatory observed the powerful burst. Right: A view of GRB 990510 - labeled OT - seen through the University of Copenhagen's 1.54-meter telescope on La Silla at the European Southern Observatory in Chile. Links to 736x461-pixel, 131K GIF. Credit: University of Copenhagen, ESO
At the same time, Beppo-SAX, an Italian-Dutch satellite, saw the burst in gamma rays and X-rays, and used its wide-field camera to provide a more precise location than BATSE can provide. The Beppo-SAX team reported that the X-ray brightness peaked at 4.3 times that of the Crab Nebula, and had an average brightness of 0.4 Crab. |
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Left: The twin peaks of the GRB 990510 light curve, as seen by BATSE, conceals even more detailed structure. Links to 451x349-pixel, 9K GIF. Credit: Marc Kippen (UAH & NASA/MSFC) and the BATSE Rapid Burst ResponseTeam. With a refined location, several southern observatories were aimed at GRB990510 in search of an visible-light counterpart (because GRB 990510 is in the Southern Hemisphere, it cannot be seen by the ROTSE array that captured the Jan. 28, 1999, burst). Astrophysicists are eager to determine if burst sources are associated with galaxies or other objects, and to measure how they fade through optical and radio wavelengths. |
The first on record was P.M. Vreeswijk of the University of Amsterdam using the 1-meter Sutherland telescope at the South African Astronomical Observatory just 9 hours after the burst was noted by BATSE. Vreeswijk is a member of the science team, led by Jan van Paradijs, that found the first GRB optical counterpart in February 1997. Van Paradijs works at the University of Alabama in Huntsville. In quick succession, sightings were reported by ANTU, one of the 8.2-meter Very Large Telescopes at ESO's Paranal Observatory - which just recently had "first light" - and the 1.3-meter Warsaw telescope in Las Campanas, Chile, operated by Poland, and other ESO telescopes. With those observations, astronomers now report a redshift of z=1.619, putting the burst source about 10 billion light years away. Astronomers are now trying to determine if it is associated with a galaxy that can't be seen until the burst fades away. The redshift is a measure of how far known spectral lines
are shifted due to the expansion of the Universe. Astronomer
Edwin Hubble noted early on in this century that objects in deep
space appear to be moving away from our own Milky Way, and the
farther away, the faster they appear to be moving. Right: The location of GRB 990510 as refined by BATSE, Beppo SAX, and Ulysses. Links to 715x439-pixel, 9KB GIF. Credit: Marc Kippen (UAH & NASA/MSFC) and the BATSE Rapid Burst ResponseTeam. It is this apparent motion that causes the shift in the spectral lines. Scientists now know that this is apparent velocity is not actually caused by distant galaxies moving through space, but instead we are observing the actual expansion of the Universe and everything in it. A redshift of 1.6 means the expansion of the universe has caused lines in the object's spectrum to be shifted by a factor of 2.6 in wavelength (1+z). |
The total energy from the burst is estimated at 1.6x1053 ergs (that's 16 followed by 52 zeroes), equivalent to our sun's output for 1.3 trillion years - about 88 times the current age of the universe. The ANTU VLT team also reports detecting slight polarization of the light, indicating that at least part of the light is emitted by electrons spiraling along strong magnetic field lines. As observed by BATSE, GRB990510 looks like two bursts with an initial burst lasting about 10 seconds, followed by a 30-second gap, and then another burst that trails off gradually until it makes a final hiccup about 90 second after the first flash of gamma rays. Left: GRB 990510 - labeled O.T. - as seen by the University of Warsaw 1.3-meter telescope at Las Campanas, with an enlarged view from ESO's Very Large Telescope in the inset. Links to 494x494-pixel, 199K GIF. Credit: UW, ESO "Bursts always look longer when they're stronger," Meegan explained. "This one may be a little longer than average, but it's not unusual." Within each of the spikes in the burst profile are four of five narrower spikes. "It looks like overlapping FREDs," Meegan said, referring to Fast-Rise, Exponential-Decay. These are bursts that appear quickly, and then weaken and fade over a long period of time. "That's common and it's one of the things that make bursts so baffling," Meegan said. "Somehow the energy release is done in episodes and the shock waves from each of these are hitting each other. The question is, why is the central engine doing things sporadically?" Meanwhile, astronomers in the Southern Hemisphere are checking back on GRB 990510 several times a day to measure the fading brightness of the optical counterpart. |
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