Six billion Earth-like planets in the Milky Way? If true, that’s astounding. But the number needs some context.
The Milky Way has up 400 billion stars. So even if there are six billion Earth-like planets, they’re still spread far and wide throughout our vast galaxy.
A new study came up with the six billion number. The co-authors are Michelle Kunimoto and Jaymie Matthews, both from the University of British Columbia. The study’s title is “Searching the Entirety of Kepler Data. II. Occurrence Rate Estimates for FGK Stars.” It’s published in The Astronomical Journal.An Earth-like world is one that’s rocky, roughly the same size as Earth, and that orbits a Sun-like, or G-Type, star. It also has to orbit that star in the habitable zone, which is a range of distance allowing for liquid water on the planet. It’s worth noting that the most common type of exoplanet we’ve detected is a Neptune-size planet far from the habitable zone.
“My calculations place an upper limit of 0.18 Earth-like planets per G-type star,” said co-author Kunimoto in a press release. “Estimating how common different kinds of planets are around different stars can provide important constraints on planet formation and evolution theories, and help optimize future missions dedicated to finding exoplanets.”
Previous work on the occurrence of Earth-like planets have come up with other numbers, from 0.02 potentially habitable Earth-like worlds per Sun-like star, up to greater than one per star.“Our Milky Way has as many as 400 billion stars, with seven per cent of them being G-type,” said co-author Matthews. “That means less than six billion stars may have Earth-like planets in our Galaxy.”
The vast majority of the exoplanets we’ve discovered have been found using the transit timing method. Automated observatories like Kepler monitored stars for the telltale dip in brightness created by a planet passing in front of its star. But that method has an unavoidable bias.
Since a larger planet will cause a much more pronounced dip in starlight than a smaller planet, we’ve found many more large gas planets than we have smaller, rocky worlds. Kepler was also more likely to spot planets with shorter orbital periods. So we can’t just take Kepler data and extrapolate it to the entire Milky Way.
In their paper, the researchers write that “Finding Earth-size planets is challenging due to their small sizes and low transit signal-to-noise ratios (S/Ns), meaning planet detection pipelines have greater difficulty uncovering them than larger planets, and a higher risk of confusing them with transit-like noise in the data.”
To get over this sampling bias, Kunimoto used a technique known as ‘forward modelling’.
“I started by simulating the full population of exoplanets around the stars Kepler searched,” she explained. “I marked each planet as ‘detected’ or ‘missed’ depending on how likely it was my planet search algorithm would have found them. Then, I compared the detected planets to my actual catalogue of planets. If the simulation produced a close match, then the initial population was likely a good representation of the actual population of planets orbiting those stars.”Their study is based on a Kepler catalogue of about 200,000 stars, and precision radius measurements from the Gaia Data Release 2. They also took into account detection efficiency, and transit-like noise signals in the data. In the end, as the authors write, “For planets with sizes 0.75–1.5 R ? orbiting in a conservatively defined habitable zone (0.99–1.70 au) around G-type stars, we place an upper limit (84.1th percentile) of <0.18 planets per star.”
But coming up with that number was only part of the study. This new work also had something to say about what’s known as “the radius gap of planets.”
The radius gap is also known as the Fulton gap, after Benjamin Fulton, an astronomer and research scientist at the NASA Exoplanet Science Institute. It describes a phenomenon outlined in a 2017 paper by Fulton and a team of researchers.In this work, the authors use a definition of habitable zone that’s becoming more common: from 0.99 to 1.70 astronomical units. They also use a lower radius limit of 0.75 Earth radii for a rocky planet, and 1.5 Earth radii for an upper limit. Other researchers are working with these same definitions.
This won’t be the final work on exoplanet populations of Earth-like planets. We’re still in the infancy of exoplanet studies, and we’re only starting to get good at finding exoplanets, and reliably characterizing their sizes, type, and positions. As Kunimoto explained in the press release, this type of research will help us refine our understanding of exoplanet populations, and how to search for them.
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