The very first image, released by the US president, will be of the "deep field"—an image taken with very long exposure time, to detect the faintest of objects in the distance—according to a person familiar with the matter.
NASA previously said Webb would achieve this shot by pointing its primary imager towards massive foreground galaxy clusters called SMACS 0723, which bend the light of objects far behind them towards the observer, an effect called "gravitational lensing."
This promises to be what NASA chief Bill Nelson called last month the "deepest image of our Universe that has ever been taken."
The rest of the first wave of images are set to be released by NASA on Tuesday.
Webb's infrared capabilities are what make it uniquely powerful, allowing it to both pierce through cosmic dust clouds and detect light from the earliest stars, which has been stretched into infrared wavelengths as the universe expanded.
This lets it peer further back in time than any previous telescope, to the period shortly after the Big Bang, 13.8 billion years ago.
"When I first saw the images... I suddenly learned three things about the Universe that I didn't know before," Dan Coe, a Space Telescope Science Institute (STSI) astronomer and expert on the early Universe, told AFP. "It's totally blown my mind."
First targets
An international committee decided the first wave of images would include the Carina Nebula, an enormous cloud of dust and gas 7,600 light years away.
Carina Nebula is famous for its towering pillars that include "Mystic Mountain," a three-light-year-tall cosmic pinnacle captured in an iconic image by the Hubble Space Telescope, until now humanity's premier space observatory.
Webb has also carried out a spectroscopy—an analysis of light that reveals detailed information—on a faraway gas giant called WASP-96 b, which was discovered in 2014.
Nearly 1,150 light-years from Earth, WASP-96 b is about half the mass of Jupiter and zips around its star in just 3.4 days.
Nestor Espinoza, an STSI astronomer, told AFP that previous exoplanet spectroscopies carried out using existing instruments were very limited compared to what Webb could do.
"It's like being in a room that is very dark and you only have a little pinhole you can look through," he said of the prior technology. Now, with Webb, "You've opened a huge window, you can see all the little details."
Million miles from Earth
Launched in December 2021 from French Guiana on an Ariane 5 rocket, Webb is orbiting the Sun at a distance of a million miles (1.6 million kilometers) from Earth, in a region of space called the second Lagrange point.
Here, it remains in a fixed position relative to the Earth and Sun, with minimal fuel required for course corrections.
A wonder of engineering, the total project cost is estimated at $10 billion, making it one of the most expensive scientific platforms ever built, comparable to the Large Hadron Collider at CERN.
Webb's primary mirror is over 21 feet (6.5 meters) wide and is made up of 18 gold-coated mirror segments. Like a camera held in one's hand, the structure must remain as stable as possible to achieve the best shots.
Charlie Atkinson, chief engineer on the James Webb Space Telescope program at lead contractor Northrop Grumman, told AFP that it wobbles no more than 17 millionths of a millimeter.
After the first images, astronomers around the globe will get shares of time on the telescope, with projects selected competitively through a process in which applicants and selectors don't know each others' identities, to minimize bias.
Thanks to an efficient launch, NASA estimates Webb has enough propellant for a 20-year life, as it works in concert with the Hubble and Spitzer space telescopes to answer fundamental questions about the cosmos.
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