“Detailed computer simulations have shown us that the gravitational pull of a planet inside a circumstellar disk can perturb gas and dust, creating spiral arms. Now, for the first time, we’re seeing these dynamical features,” said Carol Grady from Eureka Scientific, Inc., who is based at NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
Grady’s research is part of the Strategic Exploration of Exoplanets and Disks with Subaru (SEEDS), a five-year-long near-infrared study of young stars and their surrounding dust disks using the Subaru Telescope atop Mauna Kea in Hawaii. The international consortium of researchers now includes more than 100 scientists at 25 institutions.
“What we’re finding is that once these systems reach ages of a few million years, their disks begin to show a wealth of structure — rings, divots, gaps, and now spiral features,” said John Wisniewski, from the University of Washington in Seattle. “Many of these structures could be caused by planets within the disks.”
The newly imaged disk surrounds SAO 206462, an 8.7-magnitude star located about 456 light-years away in the constellation Lupus. Astronomers estimate that the system is only about 9 million years old. The gas-rich disk spans about 14 billion miles (22.5 billion kilometers), which is more than twice the size of Pluto’s orbit in our own solar system.
The Subaru near-infrared image reveals a pair of spiral features arcing along the outer disk. Theoretical models show that a single embedded planet may produce a spiral arm on each side of a disk. The structures around SAO 206462 do not form a matched pair, suggesting the presence of two unseen worlds, one for each arm. However, the research team cautions that processes unrelated to planets may give rise to these structures.
The view was made possible by the High Contrast Instrument for the Subaru Next Generation Adaptive Optics (HiCIAO), which is designed to block out harsh direct starlight.
“Together with improvements to Subaru’s adaptive optics system, which counteracts the blurring effects of Earth’s atmosphere, the telescope is operating near its theoretical performance limits,” said Motohide Tamura from the National Astronomical Observatory of Japan, which operates the telescope. “We are just beginning to see what it will do.”
“Detailed computer simulations have shown us that the gravitational pull of a planet inside a circumstellar disk can perturb gas and dust, creating spiral arms. Now, for the first time, we’re seeing these dynamical features,” said Carol Grady from Eureka Scientific, Inc., who is based at NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
Grady’s research is part of the Strategic Exploration of Exoplanets and Disks with Subaru (SEEDS), a five-year-long near-infrared study of young stars and their surrounding dust disks using the Subaru Telescope atop Mauna Kea in Hawaii. The international consortium of researchers now includes more than 100 scientists at 25 institutions.
“What we’re finding is that once these systems reach ages of a few million years, their disks begin to show a wealth of structure — rings, divots, gaps, and now spiral features,” said John Wisniewski, from the University of Washington in Seattle. “Many of these structures could be caused by planets within the disks.”
The newly imaged disk surrounds SAO 206462, an 8.7-magnitude star located about 456 light-years away in the constellation Lupus. Astronomers estimate that the system is only about 9 million years old. The gas-rich disk spans about 14 billion miles (22.5 billion kilometers), which is more than twice the size of Pluto’s orbit in our own solar system.
The Subaru near-infrared image reveals a pair of spiral features arcing along the outer disk. Theoretical models show that a single embedded planet may produce a spiral arm on each side of a disk. The structures around SAO 206462 do not form a matched pair, suggesting the presence of two unseen worlds, one for each arm. However, the research team cautions that processes unrelated to planets may give rise to these structures.
The view was made possible by the High Contrast Instrument for the Subaru Next Generation Adaptive Optics (HiCIAO), which is designed to block out harsh direct starlight.
“Together with improvements to Subaru’s adaptive optics system, which counteracts the blurring effects of Earth’s atmosphere, the telescope is operating near its theoretical performance limits,” said Motohide Tamura from the National Astronomical Observatory of Japan, which operates the telescope. “We are just beginning to see what it will do.”