No need to worry about getting fried by gamma ray burst
“But it would have to be pointed at us within 5 degrees of accuracy to do damage,” Dr. Preece said.
While these events are regular across the universe, they only happen “once per million years per galaxy.”
When a star collapses, it creates a phenomenon that looks like you have stuck your Dunkin Donuts coffee stirrer through the hole in your doughnut. The doughnut’s center is a black hole, about which not much is known. The stirrer represents an incredibly powerful energy stream that scientists think is generated by the collapse - the gamma ray burst.
The beauty part
The release notes that the research has an element of beauty to it. The big burst was icing on the cake for the UAH scientists, who detected it as they were testing out some very complex mathematical models against real data they were collecting from fourteen sensors mounted on the Fermi Large Space Telescope.
Dr. Preece is primary author and Burgess secondary author of their research, published in Science on 21 November 2013.
They had already done tests on other gamma ray bursts and were in the right place at the right time to witness the largest one ever recorded.
One reason the events leading to the origin and evolution of gamma ray bursts interest scientists is because they have many similarities to events that happened at the Big Bang. Understanding the phenomena could provide clues to the origins of the universe.
“We don’t really know what is producing these gamma rays,” said Burgess. “We think we know, and we think that it’s because of a collapsing star.”
Dr. Preece and Burgess have developed methods to measure the gamma ray spectra that may give insights into the origin of the bursts, called a jet by researchers. Instead of using theoretical constructs to test the methods, the UAH researchers are applying them to real world data from the Fermi telescope. The new methods are central to Burgess’ doctoral thesis.
“For two years, we measured various bursts,” Burgess said. “Then this burst happened and it was just perfect for what we needed to study.” They’ve found that the models work surprisingly well and do provide insights into how gamma ray bursts work.
“We’re trying to show how they are created, and from how they are created it gives us a window on where they were created within the jet,” said Burgess. “These are the most awesomely energetic things that are happening in our universe since the Big Bang.”
The equipment
None of that real-world testing would have been possible except for eight years of design and testing of the 12 low-energy sensors and two high-energy sensors that are aboard Fermi. UAH developed performance requirements and the Germans, with their subcontractors, did the detailed design work and built the detectors. Dr. Preece and Dr. Briggs developed the ground and flight software.
“NASA wanted a gamma ray instrument and we are experts in gamma rays, so we proposed it,” said Dr. Briggs, who is the UAH principle investigator for the Fermi Gamma Ray Burst Monitor (GBM), the official name of the equipment UAH, NASA and the Germans created to fly on the Fermi telescope.
From 2000 to the flight in 2008, UAH, NASA and Marshall Space Flight Center worked in partnership with the German institute and German companies to document, build and test GBM. A U.S. company, Southwest Research Institute, designed and built the flight computer.
Dr. Briggs and Dr. Preece were both deeply involved in the testing of the monitor system at locations from Huntsville to Phoenix to the District of Columbia, and in its integration into the Fermi telescope, to the point where Dr. Preece oversaw technicians as they plugged in the wiring.
UAH scientists gather at Cramer Hall weekly to teleconference with German researchers, who have the same computer equipment and software there.
— Read more in “The First Pulse of the Extremely Bright GRB 130427A: A Test Lab for Synchrotron Shocks,” Science (21 November 2013) (DOI: 10.1126/science.1242302)
