Measurements of polarized light in the afterglow of GRB 120308A by the Liverpool Telescope and its RINGO2 instrument indicate the presence of a large-scale stable magnetic field linked with a young black hole, as shown in this illustration.
Credit: NASA's Goddard Space Flight Center /S. Wiessinger
Research from an international team of scientists led by the University of Leicester has discovered for the first time that one of the most powerful events in our universe, Gamma-Ray Bursts (GRB), behave differently than previously thought.
The study, published in the prestigious scientific journal Nature, uses evidence from observation of a GRB to rule out most of the existing theoretical predictions concerning the afterglow of the explosions.
For Dr Klaas Wiersema, of the University of Leicester's Department of Physics and Astronomy, it was handy that he was up in the middle of the night tending to his three-year-old son which is when he got the alert that a GRB had occurred.
He said: "When a suitable GRB is detected by a satellite, I get a text message on my phone, and then I have to very quickly tell the observatory in Chile exactly which observations I want them to take, and how.
"This is usually a rather stressed and frantic few hours of working, as fast as possible, on my laptop throughout our night-time, and I remember very well that my son, who was three at the time, was up a lot that night too, so I kept on running back and forth between my laptop, my phone to call the observatory in Chile, and my son's cot!"
The effort was worth it- and has led to scientific findings that will change theoretical understandings of the afterglows of GRBs.
Dr Wiersema explains: "About once per day, a short, very bright flash of gamma-rays (the most energetic form of light) is detected by satellites. These flashes are called gamma-ray bursts (GRBs), and take place in galaxies far away, when a massive star collapses at the end of its life.
"These GRBs are followed by a so-called "afterglow", slowly fading emission that can be seen at all wavelengths (including visible light), for a few days to weeks."
"We know that the afterglow emission is formed by a shockwave, moving at very high velocities, in which electrons are being accelerated to tremendous energies."
"These fast moving electrons then produce the afterglow light that we detect.
When a massive star dies it explodes as a supernova.
The core of the star collapses into a black hole, and in care cases a jet is formed along the rotation axis of the newly formed black hole.
Processes in this jet emits gamma radiation, which we observe as a so-called gamma-ray burst.
Typically gamma-ray bursts last a few minutes.
When the jet hits material surrounding the dying star an afterglow is formed.
New observations of the degree of polarisation of the afterglow light has shown that the afterglow behaves differently than expected
Credit: NASA
"However, how this acceleration process actually works is very hard to study on Earth in laboratories, or using computer simulations."
"What we do, is study the polarised light of the afterglow using large optical telescopes, and special filters, that work much like the filters in Polaroid sunglasses."
Gamma-ray burst 121024A, as seen on the day of burst by ESO's Very Large Telescope (VLT) in Chile. Only a week later the source had faded completely.
Credit: Dr Klaas Wiersema, University of Leicester, UK and Dr Peter Curran, ICRAR.
Dr Wiersema says it is important to remember that light is a wave, when light is linearly polarised, it means that the wave vibrations lie in a plane; and when light is circularly polarised, it means that that this plane rotates on the sky.
He added: "Different theories for electron acceleration and light emission within the afterglow all predict different levels of linear polarisation, but theories all agreed that there should be no circular polarisation in visible light."
"This is where we come in: we decided to test this by carefully measuring both the linear and circular polarisation of one afterglow, of GRB 121024A, detected by the Swift satellite."
"Using the ESO Very Large Telescope (VLT) in Chile, we measured both the linear and circular polarisation of an afterglow with high accuracy."
"Much to our surprise we clearly detected circular polarisation, while theories predicted we should not see any at all."
"We believe that the most likely explanation is that the exact way in which electrons are accelerated within the afterglow shockwave is different from what we always thought."
"It is a very nice example of observations ruling out most of the existing theoretical predictions – exactly why observers like me are in this game!
More information: Paper: Circular polarisation in the optical afterglow of GRB 121024A, Nature, DOI: 10.1038/nature13237
Credit: NASA's Goddard Space Flight Center /S. Wiessinger
Research from an international team of scientists led by the University of Leicester has discovered for the first time that one of the most powerful events in our universe, Gamma-Ray Bursts (GRB), behave differently than previously thought.
The study, published in the prestigious scientific journal Nature, uses evidence from observation of a GRB to rule out most of the existing theoretical predictions concerning the afterglow of the explosions.
Klaas Wiersema |
He said: "When a suitable GRB is detected by a satellite, I get a text message on my phone, and then I have to very quickly tell the observatory in Chile exactly which observations I want them to take, and how.
"This is usually a rather stressed and frantic few hours of working, as fast as possible, on my laptop throughout our night-time, and I remember very well that my son, who was three at the time, was up a lot that night too, so I kept on running back and forth between my laptop, my phone to call the observatory in Chile, and my son's cot!"
The effort was worth it- and has led to scientific findings that will change theoretical understandings of the afterglows of GRBs.
Dr Wiersema explains: "About once per day, a short, very bright flash of gamma-rays (the most energetic form of light) is detected by satellites. These flashes are called gamma-ray bursts (GRBs), and take place in galaxies far away, when a massive star collapses at the end of its life.
"These GRBs are followed by a so-called "afterglow", slowly fading emission that can be seen at all wavelengths (including visible light), for a few days to weeks."
"We know that the afterglow emission is formed by a shockwave, moving at very high velocities, in which electrons are being accelerated to tremendous energies."
"These fast moving electrons then produce the afterglow light that we detect.
When a massive star dies it explodes as a supernova.
The core of the star collapses into a black hole, and in care cases a jet is formed along the rotation axis of the newly formed black hole.
Processes in this jet emits gamma radiation, which we observe as a so-called gamma-ray burst.
Typically gamma-ray bursts last a few minutes.
When the jet hits material surrounding the dying star an afterglow is formed.
New observations of the degree of polarisation of the afterglow light has shown that the afterglow behaves differently than expected
Credit: NASA
"However, how this acceleration process actually works is very hard to study on Earth in laboratories, or using computer simulations."
"What we do, is study the polarised light of the afterglow using large optical telescopes, and special filters, that work much like the filters in Polaroid sunglasses."
Gamma-ray burst 121024A, as seen on the day of burst by ESO's Very Large Telescope (VLT) in Chile. Only a week later the source had faded completely.
Credit: Dr Klaas Wiersema, University of Leicester, UK and Dr Peter Curran, ICRAR.
Dr Wiersema says it is important to remember that light is a wave, when light is linearly polarised, it means that the wave vibrations lie in a plane; and when light is circularly polarised, it means that that this plane rotates on the sky.
He added: "Different theories for electron acceleration and light emission within the afterglow all predict different levels of linear polarisation, but theories all agreed that there should be no circular polarisation in visible light."
Peter Curran, ICRAR |
"Using the ESO Very Large Telescope (VLT) in Chile, we measured both the linear and circular polarisation of an afterglow with high accuracy."
"Much to our surprise we clearly detected circular polarisation, while theories predicted we should not see any at all."
"We believe that the most likely explanation is that the exact way in which electrons are accelerated within the afterglow shockwave is different from what we always thought."
"It is a very nice example of observations ruling out most of the existing theoretical predictions – exactly why observers like me are in this game!
More information: Paper: Circular polarisation in the optical afterglow of GRB 121024A, Nature, DOI: 10.1038/nature13237
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