The work, which is based on an analysis of thousands of known exoplanets, shows that planets in our galaxy overwhelmingly fall into two groups. The first includes rocky planets up to 1.75 times the size of Earth, and the second group is made up of gaseous Neptune-like worlds between 2 to 3.5 times the size of Earth. (Neptune, by comparison, is roughly 4 times the size of Earth.)
The work includes data from NASA’s Kepler space telescope, which searches for Earth-like worlds in the habitable zones of their stars, and the W. M. Keck Observatory, which detects planets using the High Resolution Echelle Spectrometer (HIRES) on the Keck I telescope. The researchers attempted to classify these planets similarly to how biologists classify animal species.
“This is a major new division in the family tree of planets, analogous to discovering that mammals and lizards are distinct branches on the tree of life,” said Andrew Howard, professor of astronomy at Caltech and principal investigator of the new research, in a statement.
“In the solar system, there are no planets with sizes between Earth and Neptune,” added Erik Petigura, co-author of the study and a Hubble postdoctoral fellow at Caltech. “One of the great surprises from Kepler is that nearly every star has at least one planet larger than Earth but smaller than Neptune. We’d really like to know what these mysterious planets are like and why we don’t have them in our own solar system.”
A study based on the research will be published in The Astronomical Journal and a preprint version is available now in preprint version on Arxiv. The study itself is led by B.J. Fulton, a graduate student in Howard’s group who works at both Caltech and the Institute of Astronomy at the University of Hawaii.
“Astronomers like to put things in buckets,” Fulton remarked. “In this case, we have found two very distinct buckets for the majority of the Kepler planets.”
The first planet around a sun-like star was discovered in the mid-1990s. Today, there are nearly 3,500 confirmed exoplanets, with thousands more yet to be confirmed. Most of these were found by Kepler, which began its mission by staring at a fixed spot in the Cygnus constellation. Kepler monitored the stars for telltale dips of light as planets passed in front of the stars.
After the mission was no longer able to point consistently due to failing gyroscopes, Kepler began a new mission in 2013 called “K2”, where it rotates its view several times a year. It still is discovering exoplanets, but at a lower rate than before.
The Kepler catalog mostly includes planets that are very close in to their stars. Previously, the planets discovered by Kepler were known to be between the size of Earth and Neptune – but no distinct groups were known until data from the Keck telescope was used.
In general, as a planet passes in front of a star, the size of the “dip” in starlight is correlated with the size of the planet. However, to understand the size of the planet, astronomers must also know the size of the parent stars. Obtaining that information required the services of Keck, which obtained spectral data on the parent stars. The spectral data provided measurements of the stars’ sizes, which in turn, yielded more precise sizes for the planets passing in front of each star.
“Before, sorting the planets by size was like trying to sort grains of sand with your naked eye,” said Fulton. “Getting the spectra from Keck is like going out and grabbing a magnifying glass. We could see details that we couldn’t before.”
Minding the gap
The information from Keck yielded the sizes of these planets with four times more precision than what was available before. The new distribution revealed a gap between rocky Earths and mini-Neptunes. While scientists are still investigating what causes the gap in planetary sizes, they have two possible explanations.
One explanation could be that many planets are naturally Earth-sized and remain at their original size, while other ones — for reasons that are still poorly understood — acquire a lot of gassy mas.
“A little bit of hydrogen and helium gas goes a very long way. So, if a planet acquires only 1 percent of hydrogen and helium in mass, that’s enough to jump the gap,” said Howard. “These planets are like rocks with big balloons of gas around them. The hydrogen and helium that’s in the balloon doesn’t really contribute to the mass of the system as a whole, but it contributes to the volume in a tremendous way, making the planets a lot bigger in size.”
Alternatively, the gap may exist because planets that are between super-Earth and mini-Neptune size see their gas burned off when they are exposed to radiation from their parent star.
“A planet would have to get lucky to land in the gap, and then if it did, it probably wouldn’t stay there,” said Howard. “It’s unlikely for a planet to have just the right amount of gas to land in the gap. And those planets that do have enough gas can have their thin atmospheres blown off. Both scenarios likely carve out the gap in planet sizes that we observe.”
The researchers plan more study to look at the heavy elements in each planet to learn more about the worlds’ composition, which would in turn refine the predictions about how these planets are formed.
Read more at Discovery News