1/3 of planets orbiting common stars could be right for life

"These stars are excellent targets to look for small planets in an orbit where it's conceivable that water might be liquid and therefore the planet might be habitable." (Credit: Getty Images)

According to a new study, a third of the planets around the most common stars in the galaxy could be in a goldilocks orbit close enough, and gentle enough, to hold onto liquid water—and possibly harbor life.

The remaining two-thirds of the planets around these ubiquitous small stars are likely roasted by gravitational tides, sterilizing them.

“I think this result is really important for the next decade of exoplanet research, because eyes are shifting toward this population of stars,” says Sheila Sagear, a doctoral student working with Sarah Ballard, an astronomy professor at the University of Florida.

“These stars are excellent targets to look for small planets in an orbit where it’s conceivable that water might be liquid and therefore the planet might be habitable.”

Ballard and Sagear have long studied exoplanets, those worlds that orbit stars other than the sun.

Our familiar, warm, yellow sun is a relative rarity in the Milky Way. By far the most common stars are considerably smaller and cooler, sporting just half the mass of our sun at most. Billions of planets orbit these common dwarf stars in our galaxy.

Scientists think that liquid water is required for life to evolve on other planets, like it did on Earth. Because these dwarf stars are cooler, any planets would have to huddle very close to their star to draw enough warmth to host liquid water.

However, these close orbits leave the planets susceptible to extreme tidal forces caused by the star’s gravitational effect on the planets.

Sagear and Ballard measured the eccentricity—how oval the orbit is—of a sample of more than 150 planets around these dwarf stars, which are about the size of Jupiter. If a planet orbits close enough to its star, at about the distance that Mercury orbits the sun, an eccentric orbit can subject it to a process known as tidal heating. As the planet is stretched and deformed by changing gravitational forces on its irregular orbit, friction heats it up. At the extreme end, this could bake the planet, removing all chance for liquid water.

“It’s only for these small stars that the zone of habitability is close enough for these tidal forces to be relevant,” Ballard says.

Data came from NASA’s Kepler telescope, which captures information about exoplanets as they move in front of their host stars. To measure the planets’ orbits, Ballard and Sagear focused especially on how long the planets took to move across the face of the stars. Their study also relied on new data from the Gaia telescope, which measured the distance to billions of stars in the galaxy.

“The distance is really the key piece of information we were missing before that allows us to do this analysis now,” Sagear says.

Sagear and Ballard found that stars with multiple planets were the most likely to have the kind of circular orbits that allow them to retain liquid water. Stars with only one planet were the most likely to see tidal extremes that would sterilize the surface.

Since one-third of the planets in this small sample had gentle enough orbits to potentially host liquid water, that likely means that the Milky Way has hundreds of millions of promising targets to probe for signs of life outside our solar system.

The study is published in the in the Proceedings of the National Academy of Sciences.

Source: University of Florida