ALMA Creates Its First-ever Movie of Cosmic Explosion from a Radio ‘Echo’ of a Gamma-Ray Burst
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Artist impression of the “reverse shock” echoing back though the jets of
the gamma-ray burst (GRB 161219B). Credit: NRAO/AUI/NSF, S. Dagnello
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A team of astronomers using the radio telescope ALMA have studied a cataclysmic stellar explosion known as a gamma-ray burst, or GRB, and found its enduring “afterglow.” The rebound, or reverse shock, triggered by the GRB’s powerful jets slamming into surrounding debris, lasted thousands of times longer than expected. These observations provide fresh insights into the physics of GRBs, one of the Universe’s most energetic explosions.
In no time, a massive star at a distance of 2 billion light-years away, lost it battle against gravity, which lasted already a billion years, collapsing and triggering a supernova and forming a black hole at its center. These extremely large stars live hard and die young.
This new black hole belched a fleeting yet incredible intense flash of gamma rays known as a gamma-ray burst (GRB) toward Earth, where it was detected by NASA’s Neil Gehrels Swift Observatory on 19 December 2016, seconds later this burst was out of sight, however, the longer wavelengths of this event ( X-ray, visible light, and radio) were still visible so the astronomers were able to study it for weeks in several terrestrial observatories, it has been labeled GRB 161219B.
The unique capabilities of the Atacama Large Millimeter/submillimeter Array (ALMA), however, enabled a team of astronomers to make an extended study of this explosion at millimeter wavelengths, gaining new insights into this particular GRB and the size and composition of its powerful jets.
“Since ALMA sees in millimeter-wavelength light, which carries information on how the jets interact with the surrounding dust and gas, it is a powerful probe of these violent cosmic explosions,” said Tanmoy Laskar, a Jansky Postdoctoral Fellow of the National Radio Astronomy Observatory living in Berkeley, California, and lead author of the study. The results appear in the Astrophysical Journal.
These observations enabled the astronomers to produce ALMA’s first-ever time-lapse movie of a cosmic explosion, which revealed a surprisingly long-lasting reverse shockwave from the explosion echoing back through the jets. “With our current understanding of GRBs, we would normally expect a reverse shock to last only a few seconds to a minute at most. This one lasted a good portion of an entire day,” Laskar said.
A reverse shock occurs when material blasted away from a GRB by its jets runs into the surrounding gas. This encounter slows down the escaping material, sending a shockwave back down the jet.
Since jets are expected to last no more than a few minutes, a reverse shock should be an equally short-lived event. But that now appears not to be the case.
“For decades, astronomers thought this reverse shock would produce a bright flash of visible light, which has so far been really hard to find despite careful searches. Our ALMA observations show that we may have been looking in the wrong place, and that millimeter observations are our best hope of catching these cosmic fireworks,” said Carole Mundell of the University of Bath, and co-author of the study.
Instead, the light from the reverse shock shines most brightly at the millimeter wavelengths on timescales of about a day, which is most likely why it has been so difficult to detect previously. While the millimeter light was created by the reverse shock, the X-ray and visible light came from the blast-wave shock riding ahead of the jet.
“What was unique about this event,” Laskar adds, “is that as the reverse shock entered the jet, it slowly but continuously transferred the jet’s energy into the forward-moving blast wave, causing the X-ray and visible light to fade much slower than expected. Astronomers have always puzzled where this extra energy in the blast wave comes from. Thanks to ALMA, we know this energy – up to 85 percent of the total in the case of GRB 161219B – is hidden in slow-moving material within the jet itself.”
The bright reverse shock emission faded away within a week and the forward shock then shone through, giving ALMA a chance to study the geometry of the jet.
The visible light from the blast wave at this critical time, when the outflow has slowed just enough for all of the jet to become visible at Earth, was overshadowed by the emerging supernova from the exploded star. But ALMA’s observations, unencumbered by supernova light, enabled the astronomers to constrain the opening angle of the outflow from the jet to about 13 degrees.
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ALMA’s time-lapse movie showing the “afterglow” of a powerful gamma-ray
burst. These images of the millimeter-wavelength light reveal details about the
energy in the GRB’s jets. Credit:
ALMA (ESO/NAOJ/NRAO), T. Laskar; NRAO/AUI/NSF, B. Saxton
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Understanding the shape and duration of the outflow from the star is essential for determining the true energy of the burst. In this case, the astronomers find the jets contained as much energy as our Sun puts out in a billion years.
“This is a fantastical amount of energy, but it is actually one of the least energetic events we have ever seen. Why this is so remains a mystery,” says Kate Alexander, a graduate student at Harvard University who led the Very Large Array (VLA) observations reported in this study. “Though more than two billion light-years away, this GRB is actually the nearest such event for which we have measured the detailed properties of the outflow, thanks to the combined power of ALMA and the VLA.”
This is only the fourth gamma-ray burst with a convincing, multi-frequency detection of a reverse shock, the researchers note. The material around the collapsing star was about 3,000 times less dense than the gas surrounding stars in our galaxy, and these new ALMA observations suggest that such low-density environments are essential for producing reverse shock emission, which may explain why such signatures are so rare.
“Our rapid-response observations highlight the key role ALMA can play in following up transients, revealing the energy source that powers them, and using them to map the physics of the Universe to the dawn of the first stars,” concludes Laskar. “In particular, our study demonstrates that ALMA’s superb sensitivity and new rapid-response capabilities makes it the only facility that can routinely detect reverse shocks, allowing us to probe the nature of the relativistic jets in these energetic transients, and the engines that launch and feed them.”
Artist animation of a star exploding into a supernova and fueling a
gamma-ray burst. Astronomers caught the enduring "afterglow" of one
of these cataclysmic explosions with both ALMA and the VLA for the first time.
The rebound, or reverse shock, triggered by the GRB’s powerful jets slamming
into surrounding debris, lasted thousands of times longer than expected, giving
astronomers an unprecedented glimpse into the structure and dynamics of the
jets. Credit: NRAO/AUI/NSF; S. Dangello
Sources: ALMA, NRAO, Wikipedia,
