Just 25 years ago, no one knew for sure whether the stars dotting our night skies had anything circling them that resembled planets, let alone one like Earth.
Then came a NASA planet-seeker called Kepler, which starting in 2009 began finding intriguing, tell-tale blips around stars other than our sun. Almost everywhere its cameras looked, a new blip was discovered, signifying a rich abundance of “exoplanets.” Kepler’s prodigious planet-spotting—more than 1,000 of the 3,700 discovered to date—was among the first astronomical endeavors to show that the basic pattern of our solar system appears to be common elsewhere.
Now, the successor to Kepler is here. This planet-hunter, a 700-pound spacecraft called the Transiting Exoplanet Survey Satellite (TESS), is scheduled to launch next month and focus on stars nearer and brighter than those analyzed by Kepler. TESS will operate in a unique elliptical orbit, synchronized with the moon, to aim its four sophisticated cameras at roughly 200,000 stars. The mission is to detect brief decreases in brightness caused by a planet cutting across a star. In this orbit, the TESS spacecraft will remain stable for decades.
This type of pioneering astronomy—the study of planets light years away—is designed to help answer one of humanity’s oldest questions: Are we really alone?
The two-year project will examine stars that are no more than 300 light years distant—and as much as 100 times brighter than the ones Kepler detected. This relative proximity will allow for a more detailed analysis of the exoplanets, including such data as their mass, density, composition and the elements that compose their atmospheres.
TESS may very well be the arbiter of which planets we choose to explore first.
A revolution in astronomy has been playing out in the background of our lives. It took humanity 4,000 years to discover eight planets and roughly 20 years to discover 4,000 of them. Sara Seager, who pioneered study of large-exoplanet atmospheres in the late 1990s, likens the search to “a funnel toward finding another Earth.”“We have this down to a science because of Kepler and many other transit surveys,” Seager, an astrophysicist at Massachusetts Institute of Technology and a leader of the TESS research, said at a NASA news conference Wednesday.
The TESS launch is tentatively scheduled for April 16 aboard a SpaceX Falcon 9 rocket. The craft will undergo two months of orbital positioning and instrument tests before its work begins in earnest. The goal is to assemble a map of 85 percent of the sky and to suss out planets that are roughly 1 to 1.5 times the size of Earth. One central question: Does this size matter when gauging their habitability, as it did here?
Beyond the planet-hunting of Kepler and TESS, the universe may harbor many more planets than we can detect. The current “transit” method of measuring dips in a star’s light correlates only to exoplanets that are in orbits of roughly 90 degrees; other orbital inclinations would not be detectable, Seager said.
TESS is designed to work in tandem with the still-grounded James Webb Space Telescope, NASA’s $8 billion successor to the famed Hubble. Webb has suffered an additional delay, however, and won’t fly before May 2020. When both are operating, those exoplanets that TESS suggests are promising will be sent to the Webb for deeper analysis, NASA officials said.