Assembled from 208 images captured by NASA’s Transiting Exoplanet Survey Satellite (TESS) during its second year of science operations, this striking panorama of the northern sky shows familiar stars, nebulae, and nearby galaxies.
This mosaic of the northern sky incorporates 208 images taken by TESS during its second year of science operations, completed in July 2020. The mission split the northern sky into 13 sectors, each of which was imaged for nearly a month by the spacecraft’s four cameras. Among the many notable celestial objects visible: the glowing arc and obscuring dust clouds of the Milky Way (left); the Andromeda Galaxy (oval, center left), our nearest large galactic neighbor located 2.5 million light-years away; and the North America Nebula (lower left), part of a stellar factory complex 1,700 light-years away. The prominent dark lines are gaps between the detectors in TESS’ camera system. Image credit: NASA / MIT / TESS / Ethan Kruse, USRA.
TESS is the first space-based, all-sky surveyor to search for extrasolar planets.
It has four wide field-of-view optical cameras — which carry a total of 16 charge-coupled devices (CCDs) — arranged to view a long strip of the sky called an observation sector.
TESS locates planets by simultaneously monitoring many stars over large regions of the sky and watching for tiny changes in their brightness.
When a planet passes in front of its host star from our perspective, it blocks some of the star’s light, causing it to temporarily dim.
This event is called a transit, and it repeats with every orbit of the planet around the star.
This technique has proven to be the most successful planet-finding strategy so far, accounting for about three quarters of the nearly 4,300 known exoplanets.
The TESS data also allow for the study of other phenomena such as stellar variations and supernova explosions in unprecedented detail.
The northern mosaic covers less of the sky than its southern counterpart, which was imaged during the mission’s first year of operations.
For about half of the northern sectors, the TESS team decided to angle the cameras further north to minimize the impact of scattered light from Earth and the Moon. This results in a prominent gap in coverage.
During its primary mission, the cameras captured a full sector of the sky every 30 minutes. This means each CCD acquired nearly 30,800 full science images.
TESS has now begun its extended mission, during which it will spend another year imaging the southern sky.
It will revisit planets discovered in its first year, find new ones, and fill in coverage gaps from its initial survey.
Improvements to the satellite’s data collection and processing now allow TESS to return full sector images every 10 minutes and measure the brightness of thousands of stars every 20 seconds — all while continuing its previous strategy of measuring the brightness of tens of thousands of stars every two minutes.
“These changes promise to make TESS’ extended mission even more fruitful,” said TESS project scientist Dr. Padi Boyd, an astronomer at NASA’s Goddard Space Flight Center.
“Making high-precision measurements of stellar brightness at these frequencies makes TESS an extraordinary new resource for studying flaring and pulsating stars and other transient phenomena, as well as for exploring the science of transiting exoplanets.”
This article is based on a press-release provided by the National Aeronautics and Space Administration.