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James Webb Space Telescope unveils the universe as you’ve never seen or heard it before

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James Webb Space Telescope reveals a universe of sights and sounds


It’s the universe as we’ve never experienced it before. The James Webb Space Telescope is sending back incredible images of deep space so advanced scientists believe it’s going to “change astronomy forever.”

It’s not only that we can see into space and time billions of years ago. The magic is that we can see anything at all.

Although its predecessor the Hubble Space Telescope offered up some incredible sights, Webb, which was developed in partnership with NASA and the Canadian and European space agencies, is able to look even further back in time and show us more detail about what lies beyond planet Earth.

Read more:

James Webb telescope shows Neptune like you’ve never seen it before

Take the recent release of the Pillars of Creation which was first captured in 1995 by Hubble. In the original image from the area, which is considered to be a star-making part of the galaxy, pillars of gaseous clouds that look like long fingers are reaching up to the sky.

What we couldn’t see before, and what is now revealed by the Webb telescope, are all the stars hidden behind the gas.

That’s because Webb sees infrared light, which is ordinarily invisible to humans.


Pillars of Creation. Taken by the Hubble Telescope (L) and James Webb Telescope (R).

Courtesy/NASA

By picking up infrared light, Webb can see objects that are so far away, the light they emit takes over 13.5 billion years to reach Earth. That means Webb is also like a time machine in that it can see what the universe looked like back when the earth and sun were formed.

Read more:

Cosmic cliffs, dancing galaxies: James Webb Telescope’s 1st photos dazzle

However, what Webb is sending back is invisible to humans because we aren’t able to see infrared light.

So it’s the job of Joe DePasquale and Alyssa Pagan, science visuals developers at the Space Telescope Science Institute in Baltimore, to translate the information from Webb into something visible.

Joe DePasquale, senior science visuals developer, creates images from the James Webb Space Telescope.

“We can’t see in the infrared. So there has to be some level of translation here. But we use physical meaning like true physical science in order to represent the colour,” Pagan told Global’s The New Reality.

Read more:

James Webb telescope sends back more astonishing photos of distant galaxy

With the help of NASA scientists, Pagan and DePasquale break down the images into wavelengths. “We apply colour according to those wavelengths. And so the shortest wavelength filters that we have, we use blue for those. And as we move into longer and longer wavelengths, we go to greens and then reds,” DePasquale says.


Science visuals developer Alyssa Pagan translates infrared images from Webb into colours we can see.

Joey Ruffini/Global News

The end result is eyepopping images like the mountainous-looking cosmic cliffs of the Carina Nebula captured by Webb.

“What we’re seeing when we look at these images is the raw material for life,” DePasquale says.

“We’re understanding the universe. We’re understanding ourselves. It’s so intriguing to get this new perspective, this bigger picture. A lot of people can be like, ‘Oh, it makes me feel small,’ but I think for a lot of people it actually makes you feel unified, connected, part of something that’s so grand and so beautiful. So you are a part of something that’s awesome.”


An image of the Carina Nebula taken by the James Webb Space Telescope.

NASA

In their own right, these images are showstoppers, yet a Canadian scientist is now adding another level of emotion to it all.

Matt Russo, a University of Toronto physicist and a sonificiation specialist, is working with musician and friend Andrew Santaguida to add sound to the universe.

“The whole process felt really natural because we’re combining things that we’re passionate about: music, astronomy, math, computer programming, science, communication — all of these things wrapped up into one bundle,” Russo says.

Matt Russo, a University of Toronto physicist and sonification specialist, creates sounds for the Webb images.

Their first effort at sonifying an image was with the Trappist-1 solar system, first captured by NASA’S Spitzer Space Telescope in 2017.

“[It] is an amazing solar system with seven earth-sized planets. But they also happened to be locked in a musical pattern called an orbital resonance. And so that made it really natural to convert their motions into musical rhythms and pitches,” Russo says.

They did the sonification of Trappist for pure enjoyment — then NASA took notice.

“We kind of just on our own, (started) sonifying different things (NASA) had released and we would send to them and they would just start posting it on their own. And then eventually that led to us working for them professionally.”


Andrew Santaguida, musician, working with Russo to sonify Webb images.

Brent Rose/Global News

Some of the sonifications have been met with skepticism from the public, like when they did the sound for a black hole.

“There’s a real soundwave detected in space in a galaxy cluster. And we were able to see the waves in the image, which means we can extract them and re-synthesize a sound,” Russo says.

“Some outlets would say it’s an actual recorded sound of a black hole, as if you had a microphone in space, which we know would not work for several reasons. So it’s important when we do sonification to present it for exactly what it is: that it’s data converged into sound.”

Now Russo and Santaguida are working on the latest imagery from the James Webb telescope.

They’re taking the spectacular images DePasquale and Pagan have created and putting them through a software system that Russo designed.

According to Russo sometimes the sound from the data can be a pleasant surprise.  Other times they need to get a bit more creative to figure out how best to represent something in the image. Russo says they always try to be as scientifically accurate as possible.

“Where we have a little more musical input, we have to decide, for instance, which musical instrument is going to be triggered by stars,” he adds. “People seem to have an intuition that stars would make kind of a bell or chime sound.”

Their sonifications of the Webb images are now allowing people to see — and hear — the universe.

The sonifications are providing those living with visual impairments the chance to experience new insights into what’s out there.

“The whole goal is to communicate those interesting features in the image, through sound,” Russo says.

Christine Malec, a member of the visually impaired community in Toronto and an arts and culture consultant, says the sonifications by Russo and Santaguida allow her to conceptualize the images from the telescope, even though she is not able to see them.

“I had never imagined experiencing astronomy in that way,” she tells The New Reality.

Christine Malec, is a member of the visually impaired community, helping NASA make Webb images more accessible.

“When I experienced the sonification for the first time, I felt it in a way that was not intellectual; it was sensory and visceral. So I sometimes wonder if it’s what sighted people experience looking up at the night sky,” Malec says.

She now works regularly with Russo, Santaguida and NASA to help best translate the images from Webb for the benefit of people living with visual impairments.

Malec is excited about the future of space exploration and is hopeful for the future of accessible content in the science field.

“I wonder if I was a child now and came across things like sonification and image descriptions and astronomical stuff, would a career in STEM make more sense? Would it be more appealing? And I think the answer to that is yes. So I think that reason is a really good one for blind and low vision kids today to grow up with this as normal, I think it’s incredibly valuable.”



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James Webb Space Telescope spots what may be the most distant galaxy yet found

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The James Webb Space Telescope has spotted a remote, reddish galaxy shining just 350 million years after the birth of the cosmos 13.8 billion years ago, surprising astronomers who are struggling to figure out how stars and galaxies could have formed so rapidly in the wake of the Big Bang, researchers said Thursday.

“These observations just make your head explode,” Paola Santini, a co-author of a paper describing the discovery in the Astrophysical Journal Letters, said in a statement. “This is a whole new chapter in astronomy. It’s like an archaeological dig, and suddenly you find a lost city or something you didn’t know about. It’s just staggering.”

What appears to be the most distant galaxy yet detected shows up as a small red dot in this James Webb Space Telescope image. Data analysis indicates the galaxy was shining just 350 million years after the Big Bang birth of the cosmos, some 50 million years earlier than the previous record holder.

NASA, ESA, CSA, Tommaso Treu (UCLA); image processing: Zolt G. Levay (STScI)


No one yet knows when the first stars turned on after the so-called “dark ages” ended and light first began to travel freely through the universe. But “I think anything earlier than 100 million years would just be really weird,” Garth Illingworth, a Webb astronomer and professor at the University of California Santa Cruz, told reporters.

“We were mostly thinking a couple of hundred million years was likely to be where the very first things formed,” he said. “But these galaxies potentially are so massive that it may push us back earlier than that two hundred. This is really a great open question — when did the first stars form? And so these galaxies, I think, will be a pathfinder to that.”

The galaxies in question are GLASS-z12, shining 350 million years after the Big Bang, and another dating back to 450 million years, discovered after just four days of analysis as part of the Grism Lens-Amplified Survey from Space, or GLASS, observing program.

As the name implies, the extremely distant galaxies were found in light being gravitationally magnified by the mass of a nearer galaxy cluster. The two observations straddle the previous Hubble record holder, galaxy GN-z11, which was dated to about 400 million years.

The ages of the newly discovered galaxies are not yet fully confirmed — additional spectroscopic analysis is required for that — but astronomers said the observations show clear signs of numerous potentially older galaxies, which would push star formation back even closer to the Big Bang.

A second galaxy found by Webb dates back to 450 million years after the Big Bang 13.8 billion years ago. Larger galaxies in the image are members of a nearer galaxy cluster. Light from the much more distant galaxies was magnified, or gravitationally lensed, by the huge mass of the intervening cluster.

NASA, ESA, CSA, Tommaso Treu (UCLA); image processing: Zolt G. Levay (STScI)


“These galaxies would have had to have started coming together maybe just 100 million years after the Big Bang,” Illingworth said in a NASA statement. “Nobody expected that the dark ages would have ended so early. The primal universe would have been just one hundredth its current age. It’s a sliver of time in the 13.8 billion-year-old evolving cosmos.”

Tommaso Treu, principal investigator for the GLASS project and a professor at the University of California at Los Angeles, said the survey was meant “to be a way for the astronomical community to get a quick look at what surprises the universe had prepared for us.”

“And the universe and JWST did not let let us down,” he said. “As soon as we started taking data, we discovered there are many more luminous distant galaxies than we had been expecting. Somehow, the universe has managed to form galaxies faster and earlier than we thought.

“Just a few 100 million years after the Big Bang there are lots of galaxies. JWST has opened up a new frontier, bringing us closer to understanding how it all began. And we have just started to explore it.”

The James Webb Space Telescope is the most powerful space observatory ever launched, equipped with a segmented 21.3-foot-wide mirror and four sensitive cameras and spectroscopic detectors operating at less than 50 degrees above absolute zero.

The ultra-low temperature is required to enable the telescope to capture faint light that has been stretched into the infrared region of the spectrum by the expansion of space itself over the life of the cosmos.

Launched on Christmas Day last year, JWST is in its fifth month of science operations.

“JWST has been a gift that has taken months to unwrap and the result was that almost across the board, the observatory is more powerful than our pre-launch expectations,” said Jane Rigby, Webb operations project scientist at NASA’s Goddard Space Flight Center.

“The images are sharper, the pointing and guiding are more stable, with darker skies, darker backgrounds and greater, better sensitivity.” The initial results from the GLASS project, she added, “are just some of the flood of new discoveries that are pouring in. Just as we hoped,”

William Harwood

Bill Harwood has been covering the U.S. space program full-time since 1984, first as Cape Canaveral bureau chief for United Press International and now as a consultant for CBS News. He covered 129 space shuttle missions, every interplanetary flight since Voyager 2’s flyby of Neptune and scores of commercial and military launches. Based at the Kennedy Space Center in Florida, Harwood is a devoted amateur astronomer and co-author of “Comm Check: The Final Flight of Shuttle Columbia.”

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Webb Telescope’s Mid-Infrared Camera Is Fully Back in Action After Worrisome Glitch

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The Webb Space Telescope before it was packed and shipped to French Guiana for launch.
Photo: NASA

After a hiatus, one of Webb Space Telescope’s cameras will be fully operational again following an engineering test that took place last week.

Webb’s Mid-Infrared Instrument (MIRI) will resume observations using its medium-resolution spectrometry (MRS) mode by November 12, NASA announced Tuesday in a blog post. The instrument had suffered a minor glitch on August 24 due to increased friction in one of MRS’ grating wheels. Since then, the Webb science team had paused observations using that mode.

Following an in-depth investigation, the team concluded that the glitch was likely caused by “increased contact forces between the wheel central bearing assembly’s sub-components under certain conditions,” NASA wrote. That particular mechanism essentially functions like a “grating wheel” for the MRS observing mode, allowing scientists to select between short, medium, and longer wavelengths when making observations.

The investigation team then developed a set of recommendations on how to use the grating wheel mechanism during science observations. On November 2, NASA ran through an engineering test with new operational parameters based on predictions of the friction in the wheel. The test was successful, and MRS got the green light to carry out science observations once again.

The MRS mode is resuming at the perfect moment, as Webb gears up for a time-limited opportunity to see Saturn’s polar regions. The planet’s poles won’t be observable by Webb for another 20 years after that. But the science team is taking it slow at first, scheduling extra science observations for MRS in order to monitor how well it does under the new operational parameters before fully resuming its regular schedule, according to the Space Telescope Science Institute.

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Webb’s MIRI uses a camera and a spectrograph to see light in the mid-infrared part of the spectrum, wavelengths of light that are longer than what the human eye can see. MIRI has four observing modes: imaging, coronagraphic imaging, low-resolution spectroscopy, and medium-resolution spectroscopy. The MRS observing mode is useful for observing signals from the interaction of light and matter, like the emissions coming from molecules and dust in planet-forming disks.

The imaging instruments on Webb have been delivering stunning views of the cosmos. Most recently, Webb imaged the iconic Pillars of Creation, revealing the stretched-out ‘hand’ of gas and dust in exquisite detail.

More: Space Pebble That Hit Webb Telescope Caused Significant Damage, Scientists Say

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Pair of stars create “fingerprint” in photo taken by James Webb Space Telescope

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Two intertwined stars are creating what looks like a “fingerprint” in space. NASA released a photo Wednesday taken of the duo by the James Webb Space Telescope, which shows at least 17 dust rings surrounding the stars.

Two stars, known collectively as the Wolf-Rayet 140, are creating dust rings in space that resemble a fingerprint in a photo taken by NASA’s James Webb Space Telescope.

NASA


The photos were taken with the help of the telescope’s Mid-Infrared Instrument, which was created by NASA and the European Space Agency.

The stars, known collectively as Wolf-Rayet 140, are located 5,000 light years from Earth, NASA said in a news release. Each dust ring is formed as the two stars come close together during their orbit, causing gases emitting from both to compress and make the rings, NASA explained.

“Transforming gas into dust is somewhat like turning flour into bread: It requires specific conditions and ingredients,” NASA stated about the dust rings.

Each ring takes about eight years to form.

“We’re looking at over a century of dust production from this system,” astronomer Ryan Lau said.

NASA revealed that the pair is near the end of their life, which will cause them to collapse and form a black hole. Stars that are categorized as Wolf-Rayet have at least 25 times more mass than the sun, and pump out huge amounts of gas.

The duo may have shed more than half of their original mass over time, according to NASA.

Astronomers also believe the winds coming from the stars swept the surrounding area of any debris that could smear the rings, which is why they can be seen so clearly by the telescope.

“There are likely even more rings that have become so faint and dispersed, not even Webb can see them in the data,” NASA said.

The swept-up material from Wolf-Rayet stars can accumulate and form new stars. NASA revealed there is some evidence to show the sun may have also been formed that way.

Only 600 Wolf-Rayet stars have been found by astronomers in the sky, but they say there should be at least a few thousand.

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Sofia, the Historic Airplane-Borne Telescope, Lands for the Last Time

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Over the past eight years, a modified Boeing 747 jetliner has flown hundreds of flights on a unique mission: carrying a 19-ton, 2.5-meter telescope known as Sofia, or the Stratospheric Observatory for Infrared Astronomy. Flying a telescope on a jumbo jet offered a way to peer into the heavens at wavelengths that could not be glimpsed from the ground—but the ticket was expensive. So yesterday, NASA and the German space agency grounded the mission. Its final flight landed early Thursday morning at NASA’s Armstrong Flight Research Center in the desert near Los Angeles.

Sofia was an innovative way to gaze at the infrared universe. Infrared light is essentially heat radiation—but astronomers can’t probe cosmic objects like dust-enshrouded stars and galaxies without the water vapor in Earth’s atmosphere absorbing that light. That confounds attempts to observe those objects with telescopes built on mountaintops, like the observatories in Hawaii and Chile. But by soaring through the stratosphere, at an elevation of 40,000 feet or higher, Sofia could fly above that water vapor and get a much better view.

“Almost 50 percent of the energy of the universe comes out in the mid- to far infrared. Sofia has played an important and unique role for its lifetime, probing that entire wavelength range, and we’ve been able to observe all manner of phenomena that were otherwise invisible to other facilities,” says Jim De Buizer, Sofia senior scientist at NASA’s Ames Research Center in Mountain View, California.

De Buizer and the Sofia team have made a number of significant astronomical discoveries, including measuring cosmic magnetic fields permeating nearby galaxies, charting the growth of massive stars, observing Pluto’s faint shadow as it passed in front of a distant star, and even discovering water on the sunlit surface of the moon’s southern hemisphere. The data from Sofia’s final flight will map stellar nebulas and help scientists study the magnetic fields of the Sculptor starburst galaxy.

But while flying a telescope in a jet is much less expensive than launching one aboard a spacecraft, like NASA’s Spitzer and Webb space telescopes and the European Space Agency’s Herschel Space Observatory, it’s still not cheap. There are costs for the pilots, staff, engineers, and mechanics—plus a round of repairs to the aircraft that had to be made in 2018. Sofia costs NASA about $85 million per year—a significant fraction of its astrophysics budget. And that’s actually only 80 percent of the funding it needs; NASA’s German counterparts provided the rest. It was ultimately the mission’s high operating costs, relative to its scientific output, that took Sofia down.

“At the end of the day, the project itself just wasn’t productive. You’re talking about almost a Hubble cost for operations, but with a fraction of the scientific productivity,” says Casey Dreier, senior space policy adviser for the Planetary Society, a nonprofit research organization based in Pasadena, California.

This wasn’t the first time its budget came into question. In 2014, following debates about budget constraints and austerity measures, the Obama administration threatened to cut Sofia’s funding—just 11 days after the telescope and plane became operational. But the US Congress opted to continue funding it. In 2019, after Sofia completed its main mission, advancing projects that studied nebulas, stars, and galaxies in the infrared, Congress extended the project for three more years, with the possibility of additional extensions. Citing budget concerns, NASA proposed canceling the program in the 2021 fiscal year and again each of the two following years. (The 2023 fiscal year begins tomorrow.)

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One of Webb Telescope’s Tools Has a Glitch

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A view of Webb’s secondary mirror, captured during the telescope’s cryogenic testing.
Photo: Ball Aerospace

The Webb Space Telescope has been dutifully beaming back incredible images of the cosmos since its “perfect” alignment earlier this year—but nothing is entirely perfect, even a $10 billion telescope. One of Webb’s observing mechanisms has apparently run into a bit of trouble, and mission engineers are working to figure out a solution.

On August 24, a mechanism used to support Webb’s medium-resolution spectroscopy (MRS) experienced “increased friction” while being set up for a science observation, NASA said in a blog post on Tuesday. The space agency called for a meeting of an anomaly review board on September 6 to “assess the best path forward.” As the board works to analyze the issue and develop strategies to resolve it, NASA has paused observations using this particular mode.

The MRS observing mode is part of Webb’s Mid-Infrared Instrument (MIRI), which uses a camera and a spectrograph to see light in the mid-infrared part of the spectrum (wavelengths that are longer than what human eyes can see). MIRI has four observing modes: imaging, coronagraphic imaging, low-resolution spectroscopy, and medium-resolution spectroscopy. MRS is useful for observing signals from the interaction of light and matter, like the emissions coming from molecules and dust in planet-forming disks.

The glitch in question affected a mechanism that functions like a “grating wheel” for the MRS observing mode, allowing scientists to select between short, medium, and longer wavelengths when making observations using that particular mode, according to NASA.

For now, that mode is on hold while NASA tries to fix the issue. “The observatory is in good health, and MIRI’s other three observing modes – imaging, low-resolution spectroscopy, and coronagraphy – are operating normally and remain available for science observations,” the space agency wrote.

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Webb has recently wowed us with images of neighboring planets Mars and Jupiter, but the telescope is also gearing up to bring us unprecedented views of the distant universe from its perch in space 1 million miles away from Earth. Webb is expected to operate for about 20 years or longer, so hopefully it can overcome a few technical glitches along its journey.

More: Whoa, NASA Just Turned the First Webb Telescope Images Into Sounds

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Astronomers discover potential “water world” exoplanet nearby Earth that could support life

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Scientists announced this week the discovery of a nearby “super-Earth” that could potentially support life, calling it a “water world.” 

The team, led by the University of Montreal, used observations from NASA’s Transiting Exoplanet Survey Satellite (TESS), as well as telescopes on the ground, to detect the exoplanet, which is described as potentially rocky like Earth, but larger. Named TOI-1452 b, it orbits a red dwarf star about 100 light years away from our planet, which scientists say is “fairly close.” 

Scientists have long theorized the possibility of other ocean planets, but they have been difficult to confirm. TOI-1452 b is roughly 70% larger than Earth and about five times as massive, which would be consistent with having a very deep ocean — but more research is still needed. 

NASA says the planet could also potentially be an enormous rock with little or no atmosphere — or even a rocky planet with an atmosphere made up of hydrogen or helium. 

Artistic rendition of the exoplanet TOI-1452 b, a small planet that may be entirely covered in a deep ocean.

Benoît Gougeon, Université de Montréal


A year on TOI-1452 b takes just 11 days, but it gets a similar amount of light from its smaller, cooler star as Venus does from the sun. Despite its close orbit, it’s located in the “habitable zone,” meaning it could have highly-coveted liquid water on its surface. 

If this “one-of-a-kind” exoplanet were confirmed to be a water world, its ocean would be significantly deeper than Earth’s. While our planet is 70% water, oceans account for less than 1% of the planet’s mass — whereas water on TOI-1452 b could make up as much as 30% of its mass, according to one simulation. 

“TOI-1452 b is one of the best candidates for an ocean planet that we have found to date,” said study lead Charles Cadieux. “Its radius and mass suggest a much lower density than what one would expect for a planet that is basically made up of metal and rock, like Earth.”

If that simulation is accurate, it would make the planet comparable to watery moons in our solar system, like Jupiter’s Ganymede and Callisto, which scientists believe hide deep oceans under their surfaces. 

Artistic representation of the surface of TOI-1452 b, which could be an “ocean planet”, i.e. a planet entirely covered by a thick layer of liquid water. 

Benoit Gougeon, Université de Montréal.


The James Webb Space Telescope is on a mission to understand the origins of our universe, but researchers say it could take some time on the side to observe TOI-1452 b, which, “in a stroke of good fortune,” appears in the constellation Draco, a part of the sky that Webb can see during most times of the year. 

“Our observations with the Webb Telescope will be essential to better understanding TOI-1452 b,” said researcher René Doyon, who also works with one of the four science instruments of the James Webb Space Telescope. “As soon as we can, we will book time on the Webb to observe this strange and wonderful world.”

Sophie Lewis

Sophie Lewis is a social media producer and trending writer for CBS News, focusing on space and climate change.

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NASA Hubble Space Telescope, James Webb Telescope helping learn more about faraway worlds!

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NASA Exoplanets confirmed that there are more than 5,000 planets beyond our solar system. It also said that the Hubble Space Telescope and James Webb Telescope are helping learn more about faraway worlds.

You must be knowing about planets in our solar system, one of them being the planet on which we live- Earth. But do you know that NASA has confirmed more than 5,000 planets beyond our solar system, so far. Also, with the help of NASA’s Hubble Space Telescope and James Webb Telescope the research organisation is trying to learn more about the faraway worlds. Informing about the same, NASA Exoplanets, NASA team looking for planets and life beyond our solar system tweeted, “We’ve confirmed more than 5,000 planets beyond our solar system ­– so far. We’re living in an age of discovery! With @NASAWebb we’re building on science by @NASAHubble and other telescopes to learn more about the actual conditions on these faraway worlds.”

It can be known that NASA’s James Webb Space Telescope has begun to deliver amazing number of images and data. The targets for observations to come include the atmospheres of some of the strangest exoplanets found so far. “Among the best ways to understand these atmospheres, and even the planets themselves, will be the first-ever direct observations of clouds, however weird and exotic they might be,” NASA said in a report.

Also Read: Astronomers witness a Black Hole delivery system in action! Check details

“On Earth, a lot of these minerals are jewels,” said Tiffany Kataria, an exoplanet scientist at NASA’s Jet Propulsion Laboratory in Southern California. “A geologist would study them as rocks on Earth. But they can form clouds on exoplanets. That’s pretty wild.”

“These planets – hot gas giants – are among many exoplanet types confirmed in the galaxy. They could have clouds of vaporized rock because they orbit so close to their stars, making their atmospheres ferociously hot,” the report informed.

“Clouds tell us a lot about the chemistry in the atmosphere,” Kataria said. “It then becomes a question of how the clouds formed, and the formation and evolution of the system as a whole,” she added.

The Webb telescope’s many capabilities include “spectroscopy” – splitting the light Webb receives from distant stars and planets into a spectrum, a bit like a rainbow. That would allow scientists to read the types of molecules present in an exoplanet atmosphere. And that means Webb could detect specific types of minerals in clouds. Detailed study of exoplanet clouds might even yield evidence of a habitable, potentially life-bearing planet – say on a small, rocky world like Earth.

James Webb Space Telescope is an international program led by NASA with its partners, ESA (European Space Agency) and the Canadian Space Agency.

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In pictures: The Cartwheel Galaxy and the other universe mysteries revealed by James Webb

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Never before have we been able to view the universe the way the James Webb Telescope is showing it to us now.

Our naked eye would never be able to see what the telescope sees: travelling through light and space, James Webb can see the origins of the universe – something our minds can hardly begin to grasp.

Working a like a time machine, the first images shared by this powerful telescope on July 12 showed us far off galaxies, the death of stars, and the atmosphere of planets outside our solar system.

The latest image shared by the James Webb Telescope on August 2 takes another step further in our understanding of the universe, showing us what happens after two galaxies collide.

Peering through the cosmic dust created by the collision with its infrared cameras, the telescope gave us a shot of how the Cartwheel Galaxy is changing after a run-in with another smaller galaxy billions of years ago. 

Scientists think that the Cartwheel Galaxy, a ringed galaxy over 500 million lightyears away from our planet which owes its name to its bright inner ring and colourful outer ring, was once part of a large spiral like the Milky Way, before another galaxy smashed through it.

The galaxy’s whole look, which reminded scientists of the wheel of a wagon, is due to that high-speed collision, according to NASA. From the centre of collision, the galaxy’s two rings have been expanding outwards, creating that rare ringed shape.

What can James Webb see in the Cartwheel Galaxy

Scientists have never before been able to see clearly into the chaos of the Cartwheel Galaxy and make sense of it.

The Hubble Space Telescope had already peered into the galaxy, but the amount of dust surrounding the Cartwheel Galaxy prevented the telescope from observing the phenomena taking place within the galaxy.

But now, thanks to the James Webb Telescope’ infrared cameras, scientists are able to look into the galaxy’s bright centre.

To do so, an image is created by combining Webb’s Near-Infrared Camera (NIRCam) and Mid-Infrared Instrument (MIRI), which are able to see through the dust and reveal wavelengths of light impossible to observe in visible light conditions.

The image obtained shows the formation of stars in the aftermath of the galaxies colliding – a process which is not yet completely understood.

The bright core at the centre of the galaxy contains hot dust, says NASA, with the brightest areas being home to gigantic young star clusters.

What you can see on the outer ring, on the other hand, is the formation of new stars.

The Cartwheel Galaxy is still going through changes and will continue to transform, promising to reveal more secrets about how galaxies evolve over time, even though it might take billions of years.

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How Are Webb Telescope Images Colorized?

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On the left is a monochromatic image showing infrared data from Webb of the Southern Ring Nebula. On the right is a processed image showing the same view in full color.
Image: Gizmodo/NASA, ESA, CSA, and STScI

On July 12, the first full-color images from the Webb Space Telescope showed countless nebulae, galaxies, and a gassy exoplanet as they had never been seen before. But Webb only collects infrared and near-infrared light, which the human eye cannot see—so where are these gorgeous colors coming from?

Image developers on the Webb team are tasked with turning the telescope’s infrared image data into some of the most vivid views of the cosmos we’ve ever had. They assign various infrared wavelengths to colors on the visible spectrum, the familiar reds, blues, yellows, etc. But while the processed images from the Webb team aren’t literally what the telescope saw, they’re hardly inaccurate.

“Something I’ve been trying to change people’s minds about is to stop getting hung up on the idea of ‘is this what this would look like if I could fly out there in a spaceship and look at it?’” said Joe DePasquale, a senior data image developer at the Space Telescope Science Institute, in a phone call with Gizmodo. “You don’t ask a biologist if you can somehow shrink down to the size of a cell and look at the coronavirus.”

Webb’s first test images helped check its mirrors’ alignment and captured an orange-tinted shot of the Large Magellanic Cloud. Those early snapshots were not representative color images; one used a monochromatic filter (its image was grayscale) and the other just translated infrared light into the red-to-yellow visible color bands, so the team could see certain features of the cloud they imaged. But now, with the telescope up and running, the images that get released are full of blazing color, like this recent portrait of the Cartwheel Galaxy.

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Astronomy is often done outside the visible spectrum, because many of the most interesting objects in space are shining brightly in ultraviolet, x-rays, and even radio waves (which category light falls into depends on the photon’s wavelength). The Webb Telescope is designed to see infrared light, whose wavelengths are longer than red visible light but shorter than microwaves.

Infrared light can penetrate thick clouds of gas and dust in space, allowing researchers to see previously hidden secrets of the universe. Especially intriguing to scientists is that light from the early universe has been stretched as the universe has expanded, meaning what was once ultraviolet or visible light may now be infrared (what’s known as “redshifted” light).

“These are instruments that we’ve designed to extend the power of our vision, to go beyond what our eyes are capable of doing to see light that our eyes are not sensitive to, and to resolve objects that we can probably see with just our eyes,” DePasquale said. “I’m trying to bring out the most detail and the most richness of color and complexity that’s inherent in the data without actually changing anything.”

Webb’s raw images are so laden with data that they need to be scaled down before they can be translated into visible light. The images also need to be cleaned of artifacts like cosmic rays and reflections from bright stars that hit the telescope’s detectors. If you look at a Webb image before processing work is done, it’ll look like a black rectangle peppered with some white dots.

A raw image of the Carina Nebula as seen by NIRCam, before the infrared light is translated into visible wavelengths.
Image: Space Telescope Science Institute

“I think there’s some connotations that go along with ‘colorizing’ or ‘false color’ that imply there’s some process going on where we’re arbitrarily choosing colors to create a color image,” DePasquale said. “Representative color is the most preferred term for the kind of work that we do, because I think it encompasses the work that we do of translating light to create a true color image, but in a wavelength range that our eyes are not sensitive to.”

Longer infrared waves are assigned redder colors, and the shortest infrared wavelengths are assigned bluer colors. (Blue and violet light has the shortest wavelengths within the visible spectrum, while red has the longest.) The process is called chromatic ordering, and the spectrum is split into as many colors as the team needs to capture the full spectrum of light depicted in the image.

“We have filters on the instruments that collect certain wavelengths of light, which we then apply a color that is most closely what we think it will be on the [visible] spectrum,” said Alyssa Pagan, a science visuals developer at the Space Telescope Science Institute, in a phone call with Gizmodo.

The chromatic ordering depends too on what elements are being imaged. When working with narrow-band wavelengths in optical light—oxygen, ionized hydrogen, and sulfur, Pagan suggests—the latter two both emit in red. So the hydrogen might get shifted to green visible light, in order to give the viewer more information.

“It’s a balance between the art and the science, because you want to showcase science and the features, and sometimes those two things don’t necessarily work together,” Pagan added.

Webb’s first representative color images were released July 12, over six months after the telescope launched from an ESA spaceport in French Guiana. From there, Webb traveled about a million miles to L2, a point in space where gravitational effects allow spacecraft to stay in place without burning much fuel.

The telescope unfolded itself on the way to L2, so once it was there, mission scientists could get started on aligning the $10 billion observatory’s mirrors and commissioning its instruments. The telescope has four instruments: a near-infrared camera (NIRCam), a near-infrared spectrograph, a mid-infrared instrument (MIRI), and a fine guidance sensor and slitless spectrograph for pointing at targets precisely and characterizing exoplanet atmospheres.

The voluminous amounts of dust in some galaxies and nebulae are transparent to NIRCam, allowing it to capture bright stars at shorter wavelengths. MIRI, on the other hand, can observe discs of material that will give way to planets as well as dust warmed by starlight.

When telescope images are being assembled, image processors work with instrument scientists to decide which features of a given object should be highlighted in the image: its piping hot gas, perhaps, or a cool dusty tail.

When Webb imaged Stephan’s Quintet, a visual grouping of five galaxies, the finished product was a 150-million-pixel image made up of 1,000 images taken by both MIRI and NIRCam. When just seen by MIRI, though, hot dust dominates the image. In the background of the MIRI images, distant galaxies glow in different colors; DePasquale said the team calls them “skittles.”

DePasquale and Pagan helped create the Webb images as we would eventually see them, rich in color and cosmic meaning. In the case of the sweeping shot of the Carina Nebula’s cosmic cliffs, different filters captured the ionized blue gas and red dust. In initial passes at the nebula image, the gas obscured the dust’s structure, scientists asked the image processing team to “tone down the gas” a bit, Pagan said.

Collecting light in Webb’s hexagonal mirrors is only half the battle when it comes to seeing the distant universe. Translating what’s there is another beast entirely.

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