![]() ![]() Get six of our favorite Motherboard stories every day by signing up for our newsletter. Icarus is just the latest tantalizing example of the hidden gems that can be brought into focus with the help of gravitational lenses. “If we do observe events with very high magnification, that would also place extremely strong limits on the fraction of dark matter in the form of primordial black holes.”Īstronomers are harnessing the advanced techniques necessary to gaze across enormous stretches of time and space. “At the moment, the study of the high-redshift universe is limited to trying to interpret the combined light of many thousands of stars at once, which is difficult,” he added. “We could, for example, measure how quickly they are rotating, how massive they are, and how much ionizing radiation each produces.” “Even higher magnifications would allow us to learn details about Icarus and the population of luminous stars at high redshift,” Kelly told me. Future research may produce images of stars and objects located farther back in space and time, allowing astronomers to watch the exotic early stages of the universe unfold. In fact, Kelly’s paper is being released in tandem with another Nature Astronomy study, led by University of South Carolina astronomer Steven Rodney, that analyzes background transient events magnified by gravitational lensing. These “high redshift” stars, which is a term referring to the Doppler-driven optical properties of distant objects as they recede from Earth, are a goldmine of information about the early universe. Read More: Mystery Gravitational Lens Hints at Possible Primordial Black Holes, Dark Matter “The rate at which background stars should become highly magnified can be calculated with new code that we developed, and with sensitive observations with JWST we should be able to observe the events regularly,” he said. The James Webb Space Telescope (JWST), a sophisticated observatory that has been in development for decades at NASA and is currently slated for a 2020 launch, would play an essential role in pinpointing these astronomical extreme close-ups. It is possible that some of them may be amplified as much as 10,000 times. Over email, Kelly told me that even more distant stars than Icarus could, in principle, be imaged in future studies. ![]() This allowed the astronomers to study the star in fine detail, determining that it is a B-type blue supergiant, many times more massive and radiant than the yellow dwarf star at the center of our own solar system. However, Kelly’s team discovered that Icarus was magnified about 2,000 times, suggesting that a smaller object-perhaps around the size of the Sun-gave it an additional lensing assist. This cluster has been recognized as a productive cosmic telescope for many years, but it normally only amplifies the light of background objects by a few dozen times. In this record-breaking example, Icarus happened to be located behind a galaxy cluster called MACS J1149+2223, which is five billion light years from Earth. When this occurs, it’s possible for the light emitted by background objects to be magnified by the foreground objects’ intense gravitational field, giving astronomers a rare glimpse of normally unobservable stretches of the universe. Lensing occurs when a large object, such as a giant star or galaxy cluster, passes in front of more distant background objects, from our point of view on Earth. How did Kelly and his co-authors manage to witness such a remote singular object? The universe did them a solid by providing the cosmic alignment necessary for gravitational lensing, an extremely useful phenomenon for astronomers. Images of the lensing effect (left) and Icarus (right).
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