In the beginning of the 1946 holiday film classic "It's a Wonderful Life," angelic figures take on the form of a famous group of compact galaxies known as Stephan's Quintet. In reality, these galaxies aren't so heavenly. Pictures from the Hubble telescope show that Stephan's Quintet has been doing some devilish things. At least two of the galaxies have been involved in high-speed, hit-and-run accidents, which have ripped stars and gas from neighboring galaxies and tossed them into space. But the galactic carnage also has spawned new life. Arising from the wreckage are more than 100 star clusters and several dwarf galaxies. The young clusters, each harboring up to millions of stars, are shown clearly for the first time in pictures taken by Hubble's Wide Field and Planetary Camera 2.
Image Credits: NASA, Jayanne English (University of Manitoba), Sally Hunsberger (Pennsylvania State University), Zolt Levay (Space Telescope Science Institute), Sarah Gallagher (Pennsylvania State University), and Jane Charlton (Pennsylvania State University)
Science Credits: Sarah Gallagher (Pennsylvania State University), Jane Charlton (Pennsylvania State University), Sally Hunsberger (Pennsylvania State University), Dennis Zaritsky (University of Arizona), and Bradley Whitmore (Space Telescope Science Institute)
In the beginning of the 1946 holiday film classic "It's a Wonderful Life," angelic figures take on the form of a famous group of compact galaxies known as Stephan's Quintet. In reality, these galaxies aren't so heavenly. Pictures from NASA's Hubble Space Telescope show that Stephan's Quintet has been doing some devilish things. At least two of the galaxies have been involved in high-speed, hit-and-run accidents, which have ripped stars and gas from neighboring galaxies and tossed them into space.
But the galactic carnage also has spawned new life. Arising from the wreckage are more than 100 star clusters and several dwarf galaxies. The young clusters, each harboring up to millions of stars, are shown clearly for the first time in pictures taken by Hubble's Wide Field and Planetary Camera 2. Many of the clusters were born in the gaseous rubble between galaxies, far away from cozy galactic homes. Some were spawned several million years after an encounter. The clusters formed from the gravitational interactions between some members of the quintet, which compressed clouds of hydrogen gas and created stars.
Studying the star clusters and dwarf galaxies in Stephan's Quintet provides insights into how galactic encounters may have driven galaxy evolution in the early universe. The quintet resides 270 million light-years from Earth in the constellation Pegasus.
"The importance and perhaps uniqueness of Stephan's Quintet is that it may be a local example of phenomena typical of the early universe when encounters were much more common," says astronomer Sarah Gallagher of Pennsylvania State University in University Park, PA. "We may be able to look between the galaxies in other compact groups for the counterparts of the young clusters we see in the quintet as relics of similar events."
Using Hubble's sharp "eyes" to pinpoint the ages of the clusters, Gallagher and her team have tracked the rough-and-tumble history within the group of five galaxies, also known as Hickson Compact Group 92. Galaxies in compact groups are so close that most of them are bound together by gravity.
"Hubble's superb resolution allowed us to discover and pin down the ages of these star clusters," Gallagher says. Her results are published in the July 2001 issue of the Astronomical Journal.
"Analysis of the colors of the clusters indicates several distinct epochs of star formation that appear to trace the complex history of dynamical interactions in this compact group. As a cluster ages, the hottest, bluest stars die, and the color of the entire cluster becomes redder. Therefore, the redder the cluster is, the older it is. The amount of light emitted by a star cluster in different color bands can indicate its age."
Gallagher and her team identified three significant regions of star formation, which were probably created by two separate encounters. They found clusters in the long, sweeping tail and spiral arms of NGC 7319; in the tidal debris of two galaxies, NGC 7318B and NGC 7318A; and in an area north of those galaxies, dubbed the "northern starburst region."
The clusters in those regions span a range of ages, from about 2 million to more than 1 billion years old, indicating a long history of rude encounters among members of this group.
The team is particularly interested in the ages of the clusters in the northern starburst region and in NGC 7318B's elongated spiral arm. The astronomers found evidence of a series of starbursts beginning at the time of a collision 20 million years ago and continuing over millions of years. The youngest clusters are relative newborns in astronomical terms, about 2 million years old. NGC 7318B was the instigator, barreling through the region at 2 million miles per hour (3 million kilometers per hour). The harsh collision left NGC 7318B battered, stretching one of its spiral arms and stoking star formation. Although the bully galaxy appears dangerously close to NGC 7318A in the Hubble picture, it is moving too fast to merge with its close neighbor.
"It has been 20 million years since the encounter, and yet we're seeing star clusters that were born 2 million years ago," says team member Jane Charlton of Pennsylvania State University. "Previous studies suggested that the ages of these young clusters were 10 million to 20 million years old. But with the Hubble telescope we could determine that the ages were even younger. The range of ages of these young clusters indicates that the star formation in that region may be 'self-propagating.' The deaths of massive stars in each starburst generation seed the next generation."
The astronomers also uncovered 7 million-year-old clusters scattered throughout both regions, which encompass 150,000 light-years. The team is puzzled how clusters could form at the same time over a vast area.
"We don't understand how star formation could be triggered on such a large scale basically instantaneously in astronomical terms," Gallagher says. "Although such widespread coeval star formation is unusual, it is also present in another compact group, Hickson Compact Group 31. Perhaps it happens this way only in compact groups."
Another surprising discovery is the number of clusters in the northern starburst region that have formed about 150,000 light-years away from the galaxies.
"The formation of a large number of clusters in the gas between the galaxies may be common in compact groups," Charlton says. "Normally we think of stars as residents of galaxies, but here this is not the case. In these environments, interactions can spread gas between the galaxies, allowing the next perturbation in these regions to trigger star-cluster formation."
Another collision that wreaked havoc was triggered by a galaxy that is no longer part of the group. NGC 7320C plowed through the quintet several hundred million years ago, pulling out the 100,000 light-year-long tail of gaseous debris from NGC 7319 and adding gaseous fuel to the northern starburst region. Like a hit-and-run driver that scrambled from the scene of an accident, NGC 7320C is now a cozy 460,000 light-years away from the carnage and does not appear in the Hubble picture. The clusters in NGC 7319's streaming tail are 10 million to 500 million years old and may have formed at the time of the violent crash.
Not all the star clusters formed as the result of collisions. The team spied a few "orphaned" clusters, those pulled from parent galaxies, in NGC 7319's tail and in the northern starburst region. They are more than 10 billion years old and are among the oldest clusters found.
Peppered among many of the star clusters are several young dwarf galaxies. Stephan's Quintet possesses the richest known harvest of dwarf galaxies born in gaseous debris. Perhaps as many as 15 of those galaxies are in NGC 7319's long tail. The Hubble observation supports previous studies that some dwarf galaxies form in tidal tails. The telescope's clear view also revealed knots of star formation within the dwarf galaxies, as astronomers would expect in young galaxies.
"Although many dwarf galaxies form early and form the pieces from which giant galaxies are assembled, we think that a significant fraction may also form in tidal debris through the interaction of two larger galaxies," explains team member Sally Hunsberger of Pennsylvania State University. "Many older dwarfs could have formed through interactions, too, since interactions were very common in the past because galaxies were closer together. The distant galaxies seen in the Hubble Deep Field [the Hubble telescope's view of thousands of galaxies that existed in the early universe] have a disturbed structure, indicating that they are undergoing major encounters."
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