The American space agency has achieved a major milestone in its preparation of the new James Webb Space Telescope.
Engineering teams at NASA's James Webb Space Telescope Mission Operations Centre monitor progress as the observatory's second primary mirror wing rotates into position earlier this year. Photo: AFP or licensors
Engineers say they have now managed to fully focus the $10 billion observatory on a test star. The pin-sharp performance is even better than hoped, they add.
To get to this stage, all of Webb's mirrors had to be aligned to tiny fractions of the width of a human hair.
But the agency cautions that a lot of work still lies ahead before the telescope can be declared operational.
Lee Feinberg, the Nasa engineer who has led the development of Webb's optical elements, described the release of the first properly focused image as phenomenal.
"You not only see the star and the spikes from the diffraction of the star, but you see other stars in the field that are tightly focused, just like we expect, and all sorts of other interesting structure in the background," he told reporters.
"We've actually done very detailed analysis of the images we're getting, and, so far, what we're finding is that the performance is as good if not better than our most optimistic prediction."
Webb, billed as the successor to the famous Hubble Space Telescope, was launched on 25 December by an Ariane-5 rocket from French Guiana.
Its overarching goals are to take pictures of the very first stars to shine in the Universe and to probe far-off planets to see if they might be habitable.
To give Webb the necessary resolution and sensitivity to fulfil this mission, it was equipped with a 6.5m-wide primary mirror.
But this reflecting surface, made up of 18 segments, is so big it had to be folded to fit inside the nosecone of the Ariane.
Initial tasks since launch therefore have been dominated by the requirement to unpack the mirror and other optics and to get them all working in harmony.
Each of those 18 segments has had their orientation and curvature adjusted by small motors, enabling them to behave as though they're a single, monolithic surface.
"We now have achieved what's called 'diffraction limited alignment' of the telescope: The images are focused together as finely as the laws of physics allow," said Marshall Perrin who works on Webb at the Space Telescope Science Institute in Baltimore, Maryland.
The alignment work was conducted using one specific instrument on Webb - its main camera system known as NIRCam. Engineers will now have to check this set-up works for the three other instrument packages on Webb as well. This may require some small changes, or even some compromises, with the configuration as it stands today, but any adjustments are not expected to be significant.
The star used for the test image released on Wednesday is nothing particularly special, just "a generic, anonymous star" with the right level of brightness.
Webb is seeing the star at a wavelength of two microns. This is in the infrared; it's not light that would be seen by the human eye. The red colouration is for contrast.
The "spike" structures were a function of the design of Webb's primary mirror, explained Mark McCaughrean from the European Space Agency (Esa).
"The shape of those 18 hexagons imprints a faint diffraction pattern that makes bright stars look like spiky snowflakes - this isn't a problem for the science, but will give Webb images a very distinctive look," he told BBC News.
"Indeed, the fact that we can see those spikes so crisply also confirms that the mirrors have been perfectly lined up - this is brilliant news."
Take a closer look at the background features in the image. The oval shapes are great galaxies of stars that are probably billions of light-years away.
It's important to remember that this is a test image made for engineering purposes. The glorious vistas of the cosmos, like those Hubble has spoiled us with these past 30 years, will come later in the summer when science operations begin.
"The engineering images that we see today are as sharp and as crisp as the images that Hubble can take, but are at a wavelength of light that is totally invisible to Hubble," said Jane Rigby from Nasa's Goddard Space Flight Centre in Greenbelt, Maryland.
"So this is making the invisible Universe snap into very, very sharp focus."
The James Webb Space Telescope is a joint endeavour of the US, European and Canadian space agencies.
'The chance of seeing life out there in the universe'
Otago Museum director Ian Griffin told Morning Report "When I saw the first image yesterday, my head nearly exploded it because it's a beautiful picture of a star.
"But if you look in detail, you can see it surrounded by thousands and thousands of galaxies.
"This telescope is an amazing discovery machine, and even when it's being commissioned, you know these are its first images. It's not even working fully yet and you're seeing incredible stuff that's going to reveal the secrets of the universe.
"So when you think you know the technical achievement to do this - a holding telescope has been deployed at million kilometres from Earth at a temperature of minus 200 degrees and the mirrors have been aligned and it's all focused. I mean it really does some give us real hope for the future and then you know the discoveries that is going to make.
"[It] is going to really tell us about the early history of the universe, how galaxies were created and evolved, and it's also hopefully going to start looking into the atmospheres of planets around other stars, and that potentially might give us the chance of seeing life out there in the universe, which would be a discovery of immense consequence for us on Earth, realising that we're not alone in the universe.
"It's really going to address the huge questions in in astronomy and always philosophy as well."
"[It] potentially might give us the chance of seeing life out there in the universe" - Otago Museum director Ian Griffin
The telescope is in a stable point between the Earth, the Moon, and the Sun called a phttps://www.rnz.co.nz/national/programmes/nights/audio/2018832516/mathematics-and-the-lagrange-point Lagrange point].
Photo: BBC / Esa
"It's there because that's where it can get a really good view of the universe away from the the bright lights of the earth and the moon and it can get nice and cool - this is a telescope that works in the infrared region of the spectrum and its detectors have to be very, very cold to be able to get the best views of the universe, so this whole piece of kit has been specifically designed to take advantage of its position and get some incredible science over the next few years.
"That's why people like me get terribly excited when everything comes back.
"When you look at the image that was released yesterday, you can see there are lots of galaxies and some of them are bright and some of them are faint and fainter ones are actually further away, so when you take a picture of the sky you literally are looking back in time and you can see the distant galaxies and they're a different time in the universe.
"So we can figure out how the universe was working and what its composition was back then, so one of the advantages of astronomy is that you know you're not just looking at the universe as it is today, but you can study it as it was in previous times, and that's how we're going to learn about the evolution of galaxies in Cosmos."
- BBC