A pair of studies reveals how some massive stars—stars eight or more times the mass of our sun—become isolated in the universe: most often, their star clusters kick them out.
Massive stars typically reside in clusters. Isolated massive stars are called field massive stars. The papers examine most of these stars in the Small Magellanic Cloud, a dwarf galaxy near the Milky Way.
The studies, appearing in the same issue of The Astrophysical Journal, reveal how these field massive stars originate, or become so isolated. Understanding how field massive stars become isolated—whether they form in isolation or whether they become isolated by ejection from a star cluster—will help astronomers probe the conditions in which massive stars are formed. Understanding this and cluster formation is critical for understanding how galaxies evolve.
“About a quarter of all massive stars appear to be isolated, and that’s our big question,” says recent University of Michigan undergraduate Johnny Dorigo Jones. “How they’re found to be isolated, and how they got there.”
Runaway stars
Dorigo Jones shows in his paper that the vast majority of field massive stars are “runaways,” or stars ejected from clusters. Graduate student Irene Vargas-Salazar looked for field massive stars that may have formed in relative isolation by looking for evidence of tiny clusters around them. That means these relatively isolated stars could have formed in conjunction with these smaller stars. But she found very few of these faint clusters.
“Because massive stars require a lot of material to form, there are usually a lot of smaller stars around them,” Vargas-Salazar says. “My project asks specifically how many of these field massive stars could have formed in the field.”
Dorigo Jones examined how field massive stars are ejected from clusters. He looks at the two different mechanisms that produce runaways: dynamical ejection and binary supernova ejection. In the first, the massive stars are ejected from their clusters—by up to half a million miles per hour—because of unstable orbital configurations of stellar groups. In the second, a massive star is ejected when a binary pair has one star that explodes and shoots its companion out into space.
“By having the velocities and the masses of our stars, we’re able to compare the distributions of those parameters to the model predictions to determine the certain contributions from each of the ejection mechanisms,” Dorigo Jones says.
He found that dynamical ejections—ejections caused by unstable orbital configurations—were about 2 to 3 times more numerous than supernova ejections. But Dorigo Jones also found the first observational data that shows a large fraction of the field massive stars came from a combination of both dynamical and supernova ejections.
“These have been studied in the past but we have now set the first observational constraints on the numbers of these two-step runaways,” he says. “The way we reach that conclusion is we’re essentially seeing that the stars that trace the supernova ejections in our sample are a bit too numerous and too fast compared to the model predictions. You can imagine this being remedied by these stars being reaccelerated upon a supernova kick, having first been dynamically ejected.”
The researchers found that potentially up to half of the stars first thought to be from supernova ejections were first dynamically ejected.
Field massive stars in tiny clusters
Vargas-Salazar’s findings also support the idea that most field massive stars are runaways, but she looked at opposite conditions: she looked for field massive stars that formed in relative isolation in tiny clusters of smaller stars, where the massive target star is, called the “tip of the iceberg, or TIB clusters. She did this using two algorithms, “friends-of-friends” and “nearest neighbors,” to search for those clusters around 310 field massive stars in the Small Magellanic Cloud.
The “friends-of-friends” algorithm measures the number density of stars by counting how many stars there are at a specific distance from the target star and then doing the same for those stars in turn. The more tightly packed the stars are, the more likely it is to be a cluster. The “nearest neighbors” algorithm measures the number density of stars between the target star and its nearest 20 companions. The more compact and denser the group, the more likely they are to be clusters, Vargas-Salazar says.
Using statistical tests, Vargas-Salazar compared these observations with three random-field datasets and compared the known runaway massive stars to nonrunaways. She found that only a few of the field massive stars appeared to have TIB clusters around them, suggesting that very few actually formed in the field. The balance of the field stars must have originated as runaways.
“In the end, we showed that 5% or less of the stars had TIB clusters. Instead, our findings imply that the majority of stars in field samples could be runaways,” Vargas-Salazar says. “Our findings are actually supporting the result that Johnny found, wrapped in a neat little bow.”
Vargas-Salazar’s findings provide part of the answer to the question of how massive stars form, says Sally Oey, senior author on both of the papers and professor of astronomy.
“Johnny and Irene’s work are flip sides of the same coin,” Oey says. “Irene’s numbers are consistent with Johnny’s in that the vast majority of field massive stars are runaways, but that a few are not. This is a critical finding for understanding how massive stars and clusters form, and in what conditions.”
Both Dorigo Jones and Vargas-Salazar’s work had support from the National Science Foundation.
Source: University of Michigan