Friday, 24 January 2020

How Earth Climate Models Help Scientists Picture Life on Unimaginable Worlds













NASA Goddard Space Flight Center logo.

Jan. 24, 2020

In a generic brick building on the northwestern edge of NASA’s Goddard Space Flight Center campus in Greenbelt, Maryland, thousands of computers packed in racks the size of vending machines hum in a deafening chorus of data crunching. Day and night, they spit out 7 quadrillion calculations per second. These machines collectively are known as NASA’s Discover supercomputer and they are tasked with running sophisticated climate models to predict Earth’s future climate.

But now, they’re also sussing out something much farther away: whether any of the more than 4,000 curiously weird planets beyond our solar system discovered in the past two decades could support life.

Scientists are finding that the answer not only is yes, but that it’s yes under a range of surprising conditions compared to Earth. This revelation has prompted many of them to grapple with a question vital to NASA’s search for life beyond Earth. Is it possible that our notions of what makes a planet suitable for life are too limiting?


Image above: Illustration of an exoplanet. Image Credits: NASA's Goddard Space Flight Center/Chris Smith.

The next generation of powerful telescopes and space observatories will surely give us more clues. These instruments will allow scientists for the first time to analyze the atmospheres of the most tantalizing planets out there: rocky ones, like Earth, that could have an essential ingredient for life — liquid water — flowing on their surfaces.

For the time being, it’s difficult to probe far-off atmospheres. Sending a spacecraft to the closest planet outside our solar system, or exoplanet, would take 75,000 years with today’s technology. Even with powerful telescopes nearby exoplanets are virtually impossible to study in detail. The trouble is that they’re too small and too drowned out by the light of their stars for scientists to make out the faint light signatures they reflect — signatures that could reveal the chemistry of life at the surface.

In other words, detecting the ingredients of the atmospheres around these phantom planets, as many scientists like to point out, is like standing in Washington, D.C., and trying to glimpse a firefly next to a searchlight in Los Angeles. This reality makes climate models critical to exploration, said chief exoplanetary scientist Karl Stapelfeldt, who’s based at NASA’s Jet Propulsion Laboratory in Pasadena, California.

“The models make specific, testable predictions of what we should see,” he said. “These are very important for designing our future telescopes and observing strategies.”

Is the Solar System a Good Role Model?

In scanning the cosmos with large ground-based and space telescopes, astronomers have discovered an eclectic assortment of worlds that seem drawn from the imagination.

“For a long time, scientists were really focused on finding Sun- and Earth-like systems. That’s all we knew,” said Elisa Quintana, a NASA Goddard astrophysicist who led the 2014 discovery of Earth-sized planet Kepler-186f. “But we found out that there’s this whole crazy diversity in planets. We found planets as small as the Moon. We found giant planets. And we found some that orbit tiny stars, giant stars and multiple stars.”

Indeed, most of the planets detected by NASA’s Kepler space telescope and the new Transiting Exoplanet Survey Satellite, as well as ground-based observations, don’t exist in our solar system. They fall between the size of a terrestrial Earth and a gaseous Uranus, which is four times bigger than this planet.


Animation above: When a planet crosses directly between us and its star, we see the star dim slightly because the planet is blocking out a portion of the light. Measuring these dips in starlight is one technique, which is known as the “transit method,” that scientists use to identify exoplanets. Scientists make a plot called a “light curve” which shows the brightness of the star over time. Using this plot, scientists can see what percentage of the star's light the planet blocks and how long it takes the planet to cross the disk of the star, information that helps them estimate the planet's distance from the star and its mass. Animation Credits: NASA's Goddard Space Flight Center.

Planets closest in size to Earth, and most likely in theory to have habitable conditions, so far have been found only around “red dwarf” stars, which make up a vast majority of stars in the galaxy. But that’s likely because red dwarfs are smaller and dimmer than the Sun, so the signal from planets orbiting them is easier for telescopes to detect.

Because red dwarfs are small, planets have to lap uncomfortably close — closer than Mercury is to the Sun — to stay gravitationally attached to them. And because red dwarfs are cool, compared to all other stars, planets have to be closer to them to draw enough heat to allow liquid water to pool on their surfaces.


Image above: In 2014, NASA's Swift mission detected a record-setting series of X-ray flares unleashed by DG CVn, a nearby binary consisting of two red dwarf stars, illustrated here. At its peak, the initial flare was brighter in X-rays than the combined light from both stars at all wavelengths under normal conditions. Animation Credits: NASA's Goddard Space Flight Center.

Among the most alluring recent discoveries in red dwarf systems are planets like Proxima Centauri b, or simply Proxima b. It's the closest exoplanet. There are also seven rocky planets in the nearby system TRAPPIST-1. Whether or not these planets could sustain life is still a matter of debate. Scientists point out that red dwarfs can spew up to 500 times more harmful ultraviolet and X-ray radiation at their planets than the Sun ejects into the solar system. On the face of it, this environment would strip atmospheres, evaporate oceans and fry DNA on any planet close to a red dwarf.

Yet, maybe not. Earth climate models are showing that rocky exoplanets around red dwarfs could be habitable despite the radiation. 

The Magic is in the Clouds

Anthony Del Genio is a recently retired planetary climate scientist from NASA’s Goddard Institute for Space Studies in New York City. During his career he simulated the climates of Earth and of other planets, including Proxima b.

Del Genio's team recently simulated possible climates on Proxima b to test how many would leave it warm and wet enough to host life. This type of modeling work helps NASA scientists identify a handful of promising planets worthy of more rigorous study with NASA’s forthcoming James Webb Space Telescope.

“While our work can’t tell observers if any planet is habitable or not, we can tell them whether a planet is smack in the midrange of good candidates to search further,” Del Genio said.