NASA’s Transiting Exoplanet Survey Satellite (TESS) is compact but mighty, with a body just 5 feet (1.5 meters) wide. This planet hunter may end up discovering more alien worlds than NASA’s famous Kepler space telescope.
Credit: NASA/Orbital ATK
NASA’s next planet-hunting telescope will swing its gaze from point to point in the sky, searching for worlds that could be habitable.
The telescope, known as the Transiting Exoplanet Survey Satellite (TESS), will launch no earlier than Monday (April 16). Its ultimate goal is to provide a catalog of planets all over the sky. Then, even more-advanced missions can gaze at these worlds to learn more about their atmospheres.
“One of the follow-up goals is to understand the atmospheres of the planets,” mission principal investigator George Ricker, a senior scientist at the Massachusetts Institute of Technology, said in an interview in March. “You can observe the light from the host star trickling through the ring of gas around the planet as it moves across the face of its host star. Then, you can see the spectral signature of the molecules that are in the atmosphere, essentially hydrogen signatures, or other interesting chemical disequilibriums.” [Inside the Clean Room: NASA’s Exoplanet-Hunter TESS Gets Prepped for Launch]
TESS is likely too small to get very much detail from a planet, but it can act as a finder scope and pave the way for more advanced observatories. A key follow-on telescope will be NASA’s James Webb Space Telescope, whose launch was recently pushed to 2020. One of Webb’s science goals is to better characterize the atmospheres of planets. Ideally, this will include potentially habitable planets — rocky worlds that orbit their star at a distance where water can exist on their surfaces.
TESS will perform an all-sky survey, starting with the Southern Hemisphere in its first year and then moving into the Northern Hemisphere in its second year. Over the course of its operation, it will point away from the sun and keep its gaze fixed in that direction for about 27 days, before moving to the next anti-solar pointing direction for another 27 days. While doing so, it will oscillate in a 13.7-day orbit between 67,000 and 232,000 miles (108,000 to 373,000 kilometers) above Earth’s surface. [NASA’s TESS Exoplanet-Hunter in PicturesGets Prepped for Launch]
Researchers will attempt to use TESS to identify about 50 worlds that are less than four times Earth’s diameter. They hope at least a few of those planets will be in the habitable zone of their stars; if TESS achieves this goal, these worlds would add to a noteworthy catalog of nearby planet-hosting stars, including Proxima Centauri, which is just 4 light-years from Earth, and TRAPPIST-1. TESS should also find a few hundred worlds of all sorts, ranging from hot Jupiters (gas giants close to their star) to super-Earths, or worlds that are between the size of Earth and Neptune.
To find such planets, “we’re going to focus on M dwarfs,” Ricker said, referring to stars that are a little cooler and dimmer than our own sun. Potentially habitable planets must orbit closer to the star to get enough warmth, which means they will pass more frequently across their parent star’s face. More transits mean there is a better chance that TESS will see the planet in its 27-day examination of a particular part of the sky.
“The advantage is that M dwarfs are about half the size of the sun,” Ricker added, “and if you have a planet that is four times the size of the Earth, you get an [advantage] from the fact that the host star is smaller.” Those planets are easier to spot because they dim the host star more than they would around a larger star, he said.
And there’s another advantage, he noted. M dwarfs typically emit light with a wavelength of around 1 micron, which means that they are very visible in the infrared. This is the perfect spectrum for Webb, which is optimized for observations in that wavelength. This was a deliberate part of the mission design. “We wanted to find targets that are going to be optimized for follow-up observations with either existing resources on the ground or near-term space resources like [the] Hubble [Space Telescope] or Webb,” Ricker said.
Investigators hope to operate TESS for longer than its planned two-year mission, especially so that its observations will overlap with Webb’s. A more ambitious goal would be to have TESS and the European Space Agency’s Planetary Transits and Oscillations of Stars (PLATO) observatory operate at the same time, since PLATO isn’t launching until 2026. But Ricker said the engineers tried to keep consumables to a minimum; the TESS orbit will use minimal fuel, and other components of the spacecraft are built to last several years.
Visit Space.com Monday, April 16 for complete coverage of NASA’s TESS mission launch. A live webcast on the launch begins at 6 p.m. EDT (2200 GMT).