Some Super-Earths Form in Super Snowstorms

"We believe that some super-Earths form during a cosmic 'snowstorm.' Only this snowstorm envelops the whole planet and lasts millions of years," said astronomer Scott Kenyon of the Smithsonian Astrophysical Observatory.

All planets form within a disk of gas and dust surrounding a newborn star. Rocky planets form close to the star, where it is warm, while icy and gaseous planets form farther out, where it is cold. When it was young, the Sun was relatively stable, leading to a natural progression of small, rocky worlds in the hot inner solar system and large, gaseous worlds in the cold outer solar system.

In contrast, planetary systems around small red dwarf stars undergo dramatic changes in their early history. As the young star evolves, it dims. The warm inner disk starts to freeze, creating conditions where water and other volatile gases condense into snowflakes and ice pellets.

"It's like a massive cold front that sweeps inward toward the star," explained first author Grant Kennedy of Mount Stromlo Observatory in Australia. "The ices add mass to a growing planet, and also make it easier for particles to stick together. The two effects combine to produce a planet several times the size of Earth."

The disks that surround small red dwarf stars tend to contain less material than the disk that formed the solar system. Without the "snowstorms" in these smaller disks, there is not enough material to make super-Earths.

Although astronomers have discovered a few super-Earths orbiting red dwarf stars, it may be tough to find worlds hospitable to humans. All of the known super-Earths are icy worlds with no liquid water. Red dwarf stars are so dim and cool that their warm "habitable zones" are very close to the star, where there is very little planet-forming material.

"It's difficult to make anything larger than Mercury or Mars in the habitable zone of a red dwarf," said Kenyon.

The astronomers presented their calculations in a paper authored by Kennedy, Kenyon, and Benjamin Bromley (University of Utah). That paper has been accepted for publication in The Astrophysical Journal Letters and is posted online at http://arxiv.org/a … o-ph/0609140 .

The team now plans to conduct detailed numerical simulations to derive typical timescales for the formation of super-Earths around red dwarf stars.

Source: Harvard-Smithsonian Center for Astrophysics