Scientists have long wondered how tiny silicate crystals, which need high temperatures to form, have found their way into frozen comets, born in the deep freeze of the solar system’s outer edges. The crystals would have begun as non-crystallized silicate particles, part of the mix of gas and dust from which the solar system developed.
A team of astronomers believes it has found a new explanation for both where and how these crystals may have been created by using NASA’s Spitzer Space Telescope to observe the growing pains of a young Sun-like star. The study results provide new insight into the formation of planets and comets.
The researchers from Germany, Hungary, and the Netherlands found that silicate appears to have been transformed into crystalline form by an outburst from a star. They detected the infrared signature of silicate crystals on the disk of dust and gas surrounding the star EX Lupi during one of its frequent flare-ups seen by Spitzer in April 2008. These crystals were not present in Spitzer’s previous observations of the star’s disk during one of its quiet periods.
“We believe that we have observed, for the first time, ongoing crystal formation,” said Attila Juhasz of the Max Planck Institute for Astronomy in Heidelberg, Germany. “We think that the crystals were formed by thermal annealing of small particles on the surface layer of the star’s inner disk by heat from the outburst. This is a completely new scenario about how this material could be created.”
Annealing is a process in which a material is heated to a certain temperature at which some of its bonds break and then re-form, changing the material’s physical properties. It is one way that silicate dust can be transformed into crystalline form.
Scientists previously had considered two different possible scenarios in which annealing could create the silicate crystals found in comets and young stars’ disks. In one scenario, long exposure to heat from an infant star might anneal some of the silicate dust inside the disk’s center. In the other, shock waves induced by a large body within the disk might heat dust grains suddenly to the right temperature to crystallize them, after which the crystals would cool nearly as quickly.
What Juhasz and his colleagues found at EX Lupi didn’t fit either of the earlier theories. “We concluded that this is a third way in which silicate crystals may be formed with annealing, one not considered before,” said Peter Abraham of the Hungarian Academy of Sciences’ Konkoly Observatory in Budapest.
EX Lupi is a young star, possibly similar to our Sun as it was 4 or 5 billion years ago. Every few years, EX Lupi experiences outbursts that astronomers think are the result of the star gathering up mass that has accumulated in its surrounding disk. These flare-ups vary in intensity, with big eruptions occurring every 50 years or so.
The researchers observed EX Lupi with Spitzer’s infrared spectrograph in April 2008. Although the star was beginning to fade from the peak of a major outburst detected in January, it was still 30 times brighter than when it was quiet. When they compared this new view of the erupting star with Spitzer measurements made in 2005 before the eruption began, they found significant changes.
In 2005, the silicate on the surface of the star’s disk appeared to be in the form of amorphous grains of dust. In 2008, the spectrum showed the presence of crystalline silicate on top of amorphous dust. The crystals appear to be forsterite, a material often found in comets and in protoplanetary disks. The crystals also appear hot, evidence that they were created in a high-temperature process, but not by shock heating. If that were the case, they already would be cool.
“At outburst, EX Lupi became about 100 times more luminous,” said Juhasz. “Crystals formed in the surface layer of the disk but just at the distance from the star where the temperature was high enough to anneal the silicate — about 1,340° Fahrenheit (730° Celsius) — but still lower than 2,240° Fahrenheit (1,230° Celsius). Above that, the dust grains will evaporate.” The radius of this crystal formation zone is comparable to that of the terrestrial-planet region in the solar system.
“These observations show, for the first time, the actual production of crystalline silicates like those found in comets and meteorites in our own solar system,” said Michael Werner, Spitzer project scientist at NASA’s Jet Propulsion Laboratory in Pasadena, California. “So what we see in comets today may have been produced by repeated bursts of energy when the Sun was young.”