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Stardust sheds new light on origin of elements of life

Studying the chemistry of these stars helps scientists learn how the matter that makes up Earth and other planets in our galaxy left its stellar birthplaces long ago.
Provided by the University of Maryland, College Park
Carbon
An average-size star ejects material from its outer layers.
NASA
March 13, 2009
Recent evidence reveals that some stars in the center of the Milky Way Galaxy have both carbon and oxygen in the dust that surrounds them, a rare combination. An international research team made the discovery with NASA's Spitzer Telescope.

"Scientists have long expected to find carbon-rich stars in our galaxy because we know that significant quantities of carbon must be created in many such stars, but carbon had not previously shown up in the clouds of gas around these stars," said Matthew Bobrowsky, an astrophysicist in the University of Maryland's Department of Physics and one of the authors of the paper.

"Based on our findings, this is because medium-sized stars rich in carbon sometimes keep that carbon hidden until very near the end of their stellar lives, releasing it only with their final 'exhalations'," said Bobrowsky, who noted that previously scientists hadn't looked for carbon around stars that were so near the end of their active lives.

As a star burns hotter and hotter, the hydrogen gas that originally made up almost all of its mass is converted, through nuclear fusion, first to helium, and then to progressively heavier elements. The hottest region in the core fuses together the heaviest elements. And these can reach the surface of the star only when its life is almost over.

"The Big Bang produced only hydrogen and helium," Bobrowsky said. "Heavier elements like carbon and oxygen only come from getting 'cooked up' in stars. Nuclear reactions in stars created the heavier elements found in 'life as we know it'."

In the last 50,000 years of their 10 billion-year lives, Sun-sized stars expel carbon atoms along with hydrogen and helium to form a surrounding cloud of gas that soon disperses into space, perhaps to eventually become the stuff of new stars, solar systems, or even life on some earthlike planet. Much larger stars expel their heavier matter in massive explosions called supernovae.

"All the heavy elements - which astronomers call 'metal,' including all elements heavier than hydrogen and helium - on Earth were created by nuclear fusion reactions in previous generations of stars," said Bobrowsky. "Those earlier stars expelled those elements into space and then our solar system formed out of that gas containing all the heavy elements that we now find on Earth and in life on Earth."

The team of scientists used the Spitzer Space Telescope to view each star and its surrounding clouds of dust and particles, called a planetary nebula. The researchers measured the light emitted by the stars and the surrounding dust and were able to identify carbon compounds based on the wavelengths of light emitted by the stars. Looking in an area at the center of the Milky Way called the "Galactic Bulge," the team observed 26 stars and their planetary nebulae and found 21 with carbon "signatures."

But the scientists did not just find carbon around these stars; they also found oxygen in these 21 dust clouds, revealing a surprising mixture of ingredients for space dust. They report in their paper that this is likely due to a thermal pulse where a wave of high-pressure gas mixes layers of elements like carbon and oxygen and spews them out into the surrounding cloud.

The finding of carbon and oxygen in the dust clouds surrounding stars suggests a recent change of chemistry in this population of stars, according to the authors.

"Stars in the center of the Milky Way are old and 'metal-rich' with a high abundance of heavy elements," Bobrowsky said. "They are different in chemical composition than those found in the disc, farther out from the center."

Studying the chemistry of these stars helps scientists learn how the matter that makes up Earth and other planets in our galaxy left its stellar birthplaces long ago.

"If we want to understand how our galaxy, stars, planets and life in it came to be the way they are, we need to understand the creation of the chemical elements of which they are composed," Bobrowsky said.
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