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James Webb Space Telescope - Blog Posts
Crowley asking questions
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e t e r n a l b l i s s
have you seen the JWST images of the pillars of creation? i could cry just looking at them. theyâre so beautiful.
looking at them i get so emotional. i canât believe i am lucky enough to be alive in this time of beginning to understand the cosmos.
(second half has been rotated to match orientation of the first)
once i am well enough i will be going to college for astrophysics. i cannot wait to be who i know i can be.
NASA Inspires Your Crafty Creations for World Embroidery Day
Itâs amazing what you can do with a little needle and thread! For #WorldEmbroideryDay, we asked what NASA imagery inspired you. You responded with a variety of embroidered creations, highlighting our different areas of study.
Hereâs what we found:
Webbâs Carina Nebula
Wendy Edwards, a project coordinator with Earth Science Data Systems at NASA, created this embroidered piece inspired by Webbâs Carina Nebula image. Captured in infrared light, this image revealed for the first time previously invisible areas of star birth. Credit: Wendy Edwards, NASA. Pattern credit: Clare Bray, Climbing Goat Designs
Wendy Edwards, a project coordinator with Earth Science Data Systems at NASA, first learned cross stitch in middle school where she had to pick rotating electives and cross stitch/embroidery was one of the options. âWhen I look up to the stars and think about how incredibly, incomprehensibly big it is out there in the universe, Iâm reminded that the universe isnât âout thereâ at all. Weâre in it,â she said. Her latest piece focused on Webbâs image release of the Carina Nebula. The image showcased the telescopeâs ability to peer through cosmic dust, shedding new light on how stars form.
Ocean Color Imagery: Exploring the North Caspian Sea
Danielle Currie of Satellite Stitches created a piece inspired by the Caspian Sea, taken by NASAâs ocean color satellites. Credit: Danielle Currie/Satellite Stitches
Danielle Currie is an environmental professional who resides in New Brunswick, Canada. She began embroidering at the beginning of the Covid-19 pandemic as a hobby to take her mind off the stress of the unknown. Danielleâs piece is titled â46.69, 50.43,â named after the coordinates of the area of the northern Caspian Sea captured by LandSat8 in 2019.
An image of the Caspian Sea captured by Landsat 8 in 2019. Credit: NASA
Two Hubble Images of the Pillars of Creation, 1995 and 2015
Melissa Cole of Star Stuff Stitching created an embroidery piece based on the Hubble image Pillars of Creation released in 1995. Credit: Melissa Cole, Star Stuff Stitching
Melissa Cole is an award-winning fiber artist from Philadelphia, PA, USA, inspired by the beauty and vastness of the universe. They began creating their own cross stitch patterns at 14, while living with their grandparents in rural Michigan, using colored pencils and graph paper. The Pillars of Creation (Eagle Nebula, M16), released by the Hubble Telescope in 1995 when Melissa was just 11 years old, captured the imagination of a young person in a rural, religious setting, with limited access to science education.
Lauren Wright Vartanian of the shop Neurons and Nebulas created this piece inspired by the Hubble Space Telescopeâs 2015 25th anniversary re-capture of the Pillars of Creation. Credit:Â Lauren Wright Vartanian, Neurons and Nebulas
Lauren Wright Vartanian of Guelph, Ontario Canada considers herself a huge space nerd. Sheâs a multidisciplinary artist who took up hand sewing after the birth of her daughter. Sheâs currently working on the illustrations for a science themed alphabet book, made entirely out of textile art. It is being published by Firefly Books and comes out in the fall of 2024. Lauren said she was enamored by the original Pillars image released by Hubble in 1995. When Hubble released a higher resolution capture in 2015, she fell in love even further! This is her tribute to those well-known images.
James Webb Telescope Captures Pillars of Creation
Darci Lenker of Darci Lenker Art, created a rectangular version of Webbâs Pillars of Creation. Credit:Â Darci Lenker of Darci Lenker Art
Darci Lenker of Norman, Oklahoma started embroidery in college more than 20 years ago, but mainly only used it as an embellishment for her other fiber works. In 2015, she started a daily embroidery project where she planned to do one one-inch circle of embroidery every day for a year. She did a collection of miniature thread painted galaxies and nebulas for Science Museum Oklahoma in 2019. Lenker said she had previously embroidered the Hubble Telescopeâs image of Pillars of Creation and was excited to see the new Webb Telescope image of the same thing. Lenker could not wait to stitch the same piece with bolder, more vivid colors.
Milky Way
Darci Lenker of Darci Lenker Art was inspired by NASAâs imaging of the Milky Way Galaxy. Credit: Darci Lenker
In this piece, Lenker became inspired by the Milky Way Galaxy, which is organized into spiral arms of giant stars that illuminate interstellar gas and dust. The Sun is in a finger called the Orion Spur.
The Cosmic Microwave Background
This image shows an embroidery design based on the cosmic microwave background, created by Jessica Campbell, who runs Astrostitches. Inside a tan wooden frame, a colorful oval is stitched onto a black background in shades of blue, green, yellow, and a little bit of red. Credit: Jessica Campbell/ Astrostitches
Jessica Campbell obtained her PhD in astrophysics from the University of Toronto studying interstellar dust and magnetic fields in the Milky Way Galaxy. Jessica promptly taught herself how to cross-stitch in March 2020 and has since enjoyed turning astronomical observations into realistic cross-stitches. Her piece was inspired by the cosmic microwave background, which displays the oldest light in the universe.
The full-sky image of the temperature fluctuations (shown as color differences) in the cosmic microwave background, made from nine years of WMAP observations. These are the seeds of galaxies, from a time when the universe was under 400,000 years old. Credit: NASA/WMAP Science Team
GISSTEMP: NASAâs Yearly Temperature Release
Katy Mersmann, a NASA social media specialist, created this embroidered piece based on NASAâs Goddard Institute for Space Studies (GISS) global annual temperature record. Earthâs average surface temperature in 2020 tied with 2016 as the warmest year on record. Credit: Katy Mersmann, NASA
Katy Mersmann is a social media specialist at NASAâs Goddard Space Flight Center in Greenbelt, Md. She started embroidering when she was in graduate school. Many of her pieces are inspired by her work as a communicator. With climate data in particular, she was inspired by the researchers who are doing the work to understand how the planet is changing. The GISTEMP piece above is based on a data visualization of 2020 global temperature anomalies, still currently tied for the warmest year on record.
In addition to embroidery, NASA continues to inspire art in all forms. Check out other creative takes with Landsat Crafts and the James Webb Space telescope public art gallery.
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The James Webb Space Telescope has just completed a successful first year of science. Letâs celebrate by seeing the birth of Sun-like stars in this brand-new image from the Webb telescope!
This is a small star-forming region in the Rho Ophiuchi cloud complex. At 390 light-years away, it's the closest star-forming region to Earth. There are around 50 young stars here, all of them similar in mass to the Sun, or smaller. The darkest areas are the densest, where thick dust cocoons still-forming protostars. Huge red bipolar jets of molecular hydrogen dominate the image, appearing horizontally across the upper third and vertically on the right. These occur when a star first bursts through its natal envelope of cosmic dust, shooting out a pair of opposing jets into space like a newborn first stretching her arms out into the world. In contrast, the star S1 has carved out a glowing cave of dust in the lower half of the image. It is the only star in the image that is significantly more massive than the Sun.
Thanks to Webbâs sensitive instruments, we get to witness moments like this at the beginning of a starâs life. One year in, Webbâs science mission is only just getting started. The second year of observations has already been selected, with plans to build on an exciting first year that exceeded expectations. Hereâs to many more years of scientific discovery with Webb.
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Credits: NASA, ESA, CSA, STScI, Klaus Pontoppidan (STScI)
Of course Saturn brought its ring light.
On June 25, 2023, our James Webb Space Telescope made its first near-infrared observations of Saturn. The planet itself appears extremely dark at this infrared wavelength, since methane gas absorbs almost all the sunlight falling on the atmosphere. The icy rings, however, stay relatively bright, leading to Saturnâs unusual appearance in this image.
This new image of Saturn clearly shows details within the planetâs ring system, several of the planetâs moons (Dione, Enceladus, and Tethys), and even Saturnâs atmosphere in surprising and unexpected detail.
These observations from Webb are just a hint at what this observatory will add to Saturnâs story in the coming years as the science team delves deep into the data to prepare peer-reviewed results.
Download the full-resolution image, both labeled and unlabeled, from the Space Telescope Science Institute.
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12 Great Gifts from Astronomy
This is a season where our thoughts turn to others and many exchange gifts with friends and family. For astronomers, our universe is the gift that keeps on giving. Weâve learned so much about it, but every question we answer leads to new things we want to know. Stars, galaxies, planets, black holes ⌠there are endless wonders to study.
In honor of this time of year, letâs count our way through some of our favorite gifts from astronomy.
Our first astronomical gift is ⌠one planet Earth
So far, there is only one planet that weâve found that has everything needed to support life as we know it â Earth. Even though weâve discovered over 5,200 planets outside our solar system, none are quite like home. But the search continues with the help of missions like our Transiting Exoplanet Survey Satellite (TESS). And even you (yes, you!) can help in the search with citizen science programs like Planet Hunters TESS and Backyard Worlds.
Our second astronomical gift is ⌠two giant bubbles
Astronomers found out that our Milky Way galaxy is blowing bubbles â two of them! Each bubble is about 25,000 light-years tall and glows in gamma rays. Scientists using data from our Fermi Gamma-ray Space Telescope discovered these structures in 2010, and we're still learning about them.
Our third astronomical gift is ⌠three types of black holes
Most black holes fit into two size categories: stellar-mass goes up to hundreds of Suns, and supermassive starts at hundreds of thousands of Suns. But what happens between those two? Where are the midsize ones? With the help of NASAâs Hubble Space Telescope, scientists found the best evidence yet for that third, in between type that we call intermediate-mass black holes. The masses of these black holes should range from around a hundred to hundreds of thousands of times the Sunâs mass. The hunt continues for these elusive black holes.
Our fourth and fifth astronomical gifts are ⌠Stephanâs Quintet
When looking at this stunning image of Stephanâs Quintet from our James Webb Space Telescope, it seems like five galaxies are hanging around one another â but did you know that one of the galaxies is much closer than the others? Four of the five galaxies are hanging out together about 290 million light-years away, but the fifth and leftmost galaxy in the image below â called NGC 7320 â is actually closer to Earth at just 40 million light-years away.
Our sixth astronomical gift is ⌠an eclipsing six-star system
Astronomers found a six-star system where all of the stars undergo eclipses, using data from our TESS mission, a supercomputer, and automated eclipse-identifying software. The system, called TYC 7037-89-1, is located 1,900 light-years away in the constellation Eridanus and the first of its kind weâve found.
Our seventh astronomical gift is ⌠seven Earth-sized planets
In 2017, our now-retired Spitzer Space Telescope helped find seven Earth-size planets around TRAPPIST-1. It remains the largest batch of Earth-size worlds found around a single star and the most rocky planets found in one starâs habitable zone, the range of distances where conditions may be just right to allow the presence of liquid water on a planetâs surface.
Further research has helped us understand the planetsâ densities, atmospheres, and more!
Our eighth astronomical gift is ⌠an (almost) eight-foot mirror
The primary mirror on our Nancy Grace Roman Space Telescope is approximately eight feet in diameter, similar to our Hubble Space Telescope. But Roman can survey large regions of the sky over 1,000 times faster, allowing it to hunt for thousands of exoplanets and measure light from a billion galaxies.
Our ninth astronomical gift is ⌠a kilonova nine days later
In 2017, the National Science Foundation (NSF)âs Laser Interferometer Gravitational-Wave Observatory (LIGO) and European Gravitational Observatoryâs Virgo detected gravitational waves from a pair of colliding neutron stars. Less than two seconds later, our telescopes detected a burst of gamma rays from the same event. It was the first time light and gravitational waves were seen from the same cosmic source. But then nine days later, astronomers saw X-ray light produced in jets in the collisionâs aftermath. This later emission is called a kilonova, and it helped astronomers understand what the slower-moving material is made of.
Our tenth astronomical gift is ⌠NuSTARâs ten-meter-long mast
Our NuSTAR X-ray observatory is the first space telescope able to focus on high-energy X-rays. Its ten-meter-long (33 foot) mast, which deployed shortly after launch, puts NuSTARâs detectors at the perfect distance from its reflective optics to focus X-rays. NuSTAR recently celebrated 10 years since its launch in 2012.
Our eleventh astronomical gift is ⌠eleven days of observations
How long did our Hubble Space Telescope stare at a seemingly empty patch of sky to discover it was full of thousands of faint galaxies? More than 11 days of observations came together to capture this amazing image â thatâs about 1 million seconds spread over 400 orbits around Earth!
Our twelfth astronomical gift is ⌠a twelve-kilometer radius
Pulsars are collapsed stellar cores that pack the mass of our Sun into a whirling city-sized ball, compressing matter to its limits. Our NICER telescope aboard the International Space Station helped us precisely measure one called J0030 and found it had a radius of about twelve kilometers â roughly the size of Chicago! This discovery has expanded our understanding of pulsars with the most precise and reliable size measurements of any to date.
Stay tuned to NASA Universe on Twitter and Facebook to keep up with whatâs going on in the cosmos every day. You can learn more about the universe here.
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Meet Our Superhero Space Telescopes!
While the first exoplanetsâplanets beyond our solar systemâwere discovered using ground-based telescopes, the view was blurry at best. Clouds, moisture, and jittering air molecules all got in the way, limiting what we could learn about these distant worlds.
A superhero team of space telescopes has been working tirelessly to discover exoplanets and unveil their secrets. Now, a new superhero has joined the teamâthe James Webb Space Telescope. What will it find? Credit: NASA/JPL-Caltech
To capture finer detailsâdetecting atmospheres on small, rocky planets like Earth, for instance, to seek potential signs of habitabilityâastronomers knew they needed what we might call âsuperheroâ space telescopes, each with its own special power to explore our universe. Over the past few decades, a team of now-legendary space telescopes answered the call: Hubble, Chandra, Spitzer, Kepler, and TESS.
Much like scientists, space telescopes don't work alone. Hubble observes in visible lightâwith some special features (superpowers?)âChandra has X-ray vision, and TESS discovers planets by looking for tiny dips in the brightness of stars.
Kepler and Spitzer are now retired, but we're still making discoveries in the space telescopes' data. Legends! All were used to tell us more about exoplanets. Spitzer saw beyond visible light into the infrared and was able to make exoplanet weather maps! Kepler discovered more than 3,000 exoplanets.
Three space telescopes studied one fascinating planet and told us different things. Hubble found that the atmosphere of HD 189733 b is a deep blue. Spitzer estimated its temperature at 1,700 degrees Fahrenheit (935 degrees Celsius). Chandra, measuring the planetâs transit using X-rays from its star, showed that the gas giantâs atmosphere is distended by evaporation.
Adding the James Webb Space Telescope to the superhero team will make our science stronger. Its infrared views in increased ranges will make the previously unseen visible.
Soon, Webb will usher in a new era in understanding exoplanets. What will Webb discover when it studies HD 189733 b? We canât wait to find out! Super, indeed.
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See the Universe in a New Way with the Webb Space Telescope's First Images
Are you ready to see unprecedented, detailed views of the universe from the James Webb Space Telescope, the largest and most powerful space observatory ever made? Scroll down to see the first full-color images and data from Webb. Unfold the universe with us. â¨
Carina Nebula
This landscape of âmountainsâ and âvalleysâ speckled with glittering stars, called the Cosmic Cliffs, is the edge of the star-birthing Carina Nebula. Usually, the early phases of star formation are difficult to capture, but Webb can peer through cosmic dustâthanks to its extreme sensitivity, spatial resolution, and imaging capability. Protostellar jets clearly shoot out from some of these young stars in this new image.
Southern Ring Nebula
The Southern Ring Nebula is a planetary nebula: itâs an expanding cloud of gas and dust surrounding a dying star. In this new image, the nebulaâs second, dimmer star is brought into full view, as well as the gas and dust itâs throwing out around it. (The brighter star is in its own stage of stellar evolution and will probably eject its own planetary nebula in the future.) These kinds of details will help us better understand how stars evolve and transform their environments. Finally, you might notice points of light in the background. Those arenât starsâtheyâre distant galaxies.
Stephanâs Quintet
Stephanâs Quintet, a visual grouping of five galaxies near each other, was discovered in 1877 and is best known for being prominently featured in the holiday classic, âItâs a Wonderful Life.â This new image brings the galaxy group from the silver screen to your screen in an enormous mosaic that is Webbâs largest image to date. The mosaic covers about one-fifth of the Moonâs diameter; it contains over 150 million pixels and is constructed from almost 1,000 separate image files. Never-before-seen details are on display: sparkling clusters of millions of young stars, fresh star births, sweeping tails of gas, dust and stars, and huge shock waves paint a dramatic picture of galactic interactions.
WASP-96 b
WASP-96 b is a giant, mostly gas planet outside our solar system, discovered in 2014. Webbâs Near-Infrared Imager and Slitless Spectrograph (NIRISS) measured light from the WASP-96 system as the planet moved across the star. The light curve confirmed previous observations, but the transmission spectrum revealed new properties of the planet: an unambiguous signature of water, indications of haze, and evidence of clouds in the atmosphere. This discovery marks a giant leap forward in the quest to find potentially habitable planets beyond Earth.
Webb's First Deep Field
This image of galaxy cluster SMACS 0723, known as Webbâs First Deep Field, looks 4.6 billion years into the past. Looking at infrared wavelengths beyond Hubbleâs deepest fields, Webbâs sharp near-infrared view reveals thousands of galaxiesâincluding the faintest objects ever observed in the infraredâin the most detailed view of the early universe to date. We can now see tiny, faint structures weâve never seen before, like star clusters and diffuse features and soon, weâll begin to learn more about the galaxiesâ masses, ages, histories, and compositions.
These images and data are just the beginning of what the observatory will find. It will study every phase in the history of our Universe, ranging from the first luminous glows after the Big Bang, to the formation of solar systems capable of supporting life on planets like Earth, to the evolution of our own Solar System.
Make sure to follow us on Tumblr for your regular dose of spaceâand for milestones like this!
Credits: NASA, ESA, CSA, and STScI
A View into the Past
Our Hubble Space Telescope just found the farthest individual star ever seen to date!
Nicknamed âEarendelâ (âmorning starâ in Old English), this star existed within the first billion years after the universeâs birth in the big bang. Earendel is so far away from Earth that its light has taken 12.9 billion years to reach us, far eclipsing the previous single-star record holder whose light took 9 billion years to reach us.
Though Earendel is at least 50 times the mass of our Sun and millions of times as bright, weâd normally be unable to see it from Earth. However, the mass of a huge galaxy cluster between us and Earendel has created a powerful natural magnifying glass. Astronomers expect that the star will be highly magnified for years.
Earendel will be observed by NASAâs James Webb Space Telescope. Webb's high sensitivity to infrared light is needed to learn more about this star, because its light is stretched to longer infrared wavelengths due to the universe's expansion.
Ever wanted to look back in time? This week, weâre launching a kind of time machine â a telescope so powerful it will help us see back some of the first stars and galaxies made after the Big Bang.
The James Webb Space Telescope is the largest and most advanced telescope weâve ever put in space. With revolutionary technology, it will study 13.5 billion years of cosmic history and help humanity understand our place in the stars.
Tomorrow, Dec. 25, at 7:20 a.m. ET (12:20 UTC), the Webb Telescope is set to launch from French Guiana, beginning a 29-day journey to a spot a million miles away.
How to Watch:
In English:
Dec. 25
Live coverage starts at 6:00 a.m. ET/11:00 UTC
Facebook, YouTube, Twitter, Twitch
In Spanish:
Dec. 25
Live coverage starts at 6:30 a.m. ET/11:30 UTC
Facebook, YouTube, Twitter
Once Webb launches, the journey has only just begun. The telescope will begin a 2-week-long process of unfolding itself in space before settling in to explore the universe in ways weâve never seen before.
Follow along on Twitter, Facebook and Instagram and with #UnfoldTheUniverse.
Thatâs a wrap! Thank you for all the wonderful questions. James Webb Space Telescope Planetary Scientist Dr. Naomi Rowe-Gurney answered questions about the science goals, capabilities, and her hopes for the world's most powerful telescope.
Check out her full Answer Time for more: Career | Science Goals | Capabilities
We hope you enjoyed today and learned something new about the Webb mission! Donât miss the historic launch of this first-of-its kind space observatory. Tune in to NASA TV HERE on Dec. 22 starting at 7:20 a.m. EST (12:20 UTC).
If todayâs Answer Time got you excited, explore all the ways you can engage with the mission before launch! Join our #UnfoldTheUniverse art challenge, our virtual social event with international space agencies, and countdown to liftoff with us. Check out all the ways to participate HERE.
Make sure to follow us on Tumblr for your regular dose of space!
Questions coming up fromâŚ.
@teamadamsperret: Congrats on your PhD!! When people ask what you do, what's your reply?
@Anonymous: How does it feel, working in NASA?
@moonlighy: How did you find your love for this job?
@redbullanddepression: what the prettiest star in the sky in your opinion? also, you are a great role model as a queer woman who is attending university next year to major in aerospace engineering!!!
Hi.dr.naomi.i have 2 questions.
1.Can this JAMES WEB T.S able to see Mercury, Venus and certain stars that are close to the sun either. I.
2.Why is the James Webb t.s.mirror yellow?
Any specific reason for this
Will it take pictures of Pluto?
What would be the ideal discovery to make with the Webb Telescope? Or what would you love to find with it?
Does Webb have resolution to look more closely at nearby objects, like Mars or even Earth? Or just far things?
Hello. I'm curious what new feature the james webb brings to the table, like its ability to detect in infrared, that you are most excited about? What are you most interested to look into with this new telescope?
How exactly will it work? And whats the goal of the project?
Do you have any protections against asteroids?
Concerning the new telescope -out of curiosity- what is the maximum distance it can view planets, galaxies, objects, anything up to -in terms of common/metric measurement, and/or years (if applicable) etc.? -Rose
What does âchemical fingerprintsâ mean? What chemicals indicate possible life on other planets?
Will the James Webb Telescope also be able to spot out signs of life on habitable worlds?
Questions coming up fromâŚ.
@maybeinanotherworld: JWST IS HAPPENING! How are all of you feeling about this?
@Anonymous: How powerful is this telescope, exactly?
@Anonymous: Why are the mirrors on it yellow?
@foeofcolor: How long is this estimated to last for? Like how long will it be able to function in space by estimates?
Who's ready to #UnfoldTheUniverse? The James Webb Space Telescope Answer Time with expert Dr. Naomi Rowe-Gurney is LIVE! Stay tuned for talks about the science goals, capabilities, and hopes for the world's most powerful telescope. View ALL the answers HERE.
Make sure to follow us on Tumblr for your regular dose of space!
How will the James Webb Space Telescope change how we see the universe? Ask an expert!
The James Webb Space Telescope is launching on December 22, 2021. Webbâs revolutionary technology will explore every phase of cosmic historyâfrom within our solar system to the most distant observable galaxies in the early universe, to everything in between. Postdoctoral Research Associate Naomi Rowe-Gurney will be taking your questions about Webb and Webb science in an Answer Time session on Tuesday, December 14 from noon to 1 p.m EST here on our Tumblr!
đ¨ Ask your questions now by visiting http://nasa.tumblr.com/ask.
Dr. Naomi Rowe-Gurney recently completed her PhD at the University of Leicester and is now working at NASA Goddard Space Flight Center as a postdoc through Howard University. As a planetary scientist for the James Webb Space Telescope, sheâs an expert on the atmospheres of the ice giants in our solar system â Uranus and Neptune â and how the Webb telescope will be able to learn more about them.
The James Webb Space Telescope â fun facts:
Webb is so big it has to fold origami-style to fit into its rocket and will unfold like a âTransformerâ in space.
Webb is about 100 times more powerful than the Hubble Space Telescope and designed to see the infrared, a region Hubble can only peek at.
With unprecedented sensitivity, it will peer back in time over 13.5 billion years to see the first galaxies born after the Big Bangââa part of space weâve never seen.
It will study galaxies near and far, young and old, to understand how they evolve.
Webb will explore distant worlds and study the atmospheres of planets orbiting other stars, known as exoplanets, searching for chemical fingerprints of possible habitability.
Make sure to follow us on Tumblr for your regular dose of space!
Decoding Nebulae
We can agree that nebulae are some of the most majestic-looking objects in the universe. But what are they exactly? Nebulae are giant clouds of gas and dust in space. Theyâre commonly associated with two parts of the life cycle of stars: First, they can be nurseries forming new baby stars. Second, expanding clouds of gas and dust can mark where stars have died.
Not all nebulae are alike, and their different appearances tell us what's happening around them. Since not all nebulae emit light of their own, there are different ways that the clouds of gas and dust reveal themselves. Some nebulae scatter the light of stars hiding in or near them. These are called reflection nebulae and are a bit like seeing a street lamp illuminate the fog around it.
In another type, called emission nebulae, stars heat up the clouds of gas, whose chemicals respond by glowing in different colors. Think of it like a neon sign hanging in a shop window!
Finally there are nebulae with dust so thick that weâre unable to see the visible light from young stars shine through it. These are called dark nebulae.
Our missions help us see nebulae and identify the different elements that oftentimes light them up.
The Hubble Space Telescope is able to observe the cosmos in multiple wavelengths of light, ranging from ultraviolet, visible, and near-infrared. Hubble peered at the iconic Eagle Nebula in visible and infrared light, revealing these grand spires of dust and countless stars within and around them.
The Chandra X-ray Observatory studies the universe in X-ray light! The spacecraft is helping scientists see features within nebulae that might otherwise be hidden by gas and dust when viewed in longer wavelengths like visible and infrared light. In the Crab Nebula, Chandra sees high-energy X-rays from a pulsar (a type of rapidly spinning neutron star, which is the crushed, city-sized core of a star that exploded as a supernova).
The James Webb Space Telescope will primarily observe the infrared universe. With Webb, scientists will peer deep into clouds of dust and gas to study how stars and planetary systems form.
The Spitzer Space Telescope studied the cosmos for over 16 years before retiring in 2020. With the help of its detectors, Spitzer revealed unknown materials hiding in nebulae â like oddly-shaped molecules and soot-like materials, which were found in the California Nebula.
Studying nebulae helps scientists understand the life cycle of stars. Did you know our Sun got its start in a stellar nursery? Over 4.5 billion years ago, some gas and dust in a nebula clumped together due to gravity, and a baby Sun was born. The process to form a baby star itself can take a million years or more!
After billions more years, our Sun will eventually puff into a huge red giant star before leaving behind a beautiful planetary nebula (so-called because astronomers looking through early telescopes thought they resembled planets), along with a small, dense object called a white dwarf that will cool down very slowly. In fact, we donât think the universe is old enough yet for any white dwarfs to have cooled down completely.
Since the Sun will live so much longer than us, scientists can't observe its whole life cycle directly ... but they can study tons of other stars and nebulae at different phases of their lives and draw conclusions about where our Sun came from and where it's headed. While studying nebulae, weâre seeing the past, present, and future of our Sun and trillions of others like it in the cosmos.
To keep up with the most recent cosmic news, follow NASA Universe on Twitter and Facebook.
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10 Ways the Webb Telescope âTrainsâ for Space
The James Webb Space Telescope will peer at the first stars and galaxies as a cosmic time machine, look beyond to distant worlds, and unlock the mysteries of the universe. But before it can do any of those things, it needs to âtrainâ for traveling to its destination â 1 million miles away from Earth!
So how does Webb get ready for space while itâs still on the ground? Practice makes perfect. Different components of the telescope were first tested on their own, but now a fully-assembled Webb is putting all of its training together. Here are 10 types of tests that Webb went through to prepare for its epic journey:
1. Sounding Off
A rocket launch is 100 times more intense and four times louder than a rock concert! (Thatâs according to Paul Geithner, Webbâs deputy project manager â technical.) To simulate that level of extreme noise, Webbâs full structure was blasted with powerful sound waves during its observatory-level acoustic testing in August.
2. Shaking It Up
Webb will also have to withstand a super-bumpy ride as it launches â like a plane takeoff, but with a lot more shaking! The observatory was carefully folded into its launch position, placed onto a shaker table, and vibrated from 5 to 100 times per second to match the speeds of Webbâs launch vehicle, an Ariane 5 rocket.
3. All Systems Go
In July, Webb performed a rigorous test of its software and electrical systems as a fully connected telescope. Each line of code for Webb was tested and then retested as different lines were combined into Webbâs larger software components. To complete this test, Webb team members were staffed 24 hours a day for 15 consecutive days!
4. Hanging Out
After launch, Webb is designed to unfold (like origami in reverse) from its folded launch position into its operational form. Without recharging, the telescopeâs onboard battery would only last a few hours, so it will be up to Webbâs 20-foot solar array to harness the Sunâs energy for all of the telescopeâs electrical needs. To mimic the zero-gravity conditions of space, Webb technicians tested the solar array by hanging it sideways.
5. Time to Stretch
The tower connects the upper and lower halves of Webb. Once Webb is in space, the tower will extend 48 inches (1.2 meters) upward to create a gap between the two halves of the telescope. Then all five layers of Webbâs sunshield will slowly unfurl and stretch out, forming what will look like a giant kite in space. Both the tower and sunshield will help different sections of Webb maintain their ideal temperatures.
For these steps, engineers designed an ingenious system of cables, pulleys and weights to counter the effects of Earthâs gravity. 6. Dance of the Mirrors
Unfolding Webbâs mirrors will involve some dance-like choreography. First, a support structure will gracefully unfold to place the circular secondary mirror out in front of the primary mirror. Although small, the secondary mirror will play a big role: focusing light from the primary mirror to send to Webbâs scientific instruments.
Next, Webbâs iconic primary mirror will fully extend so that all 18 hexagonal segments are in view. At 6.5 meters (21 feet 4-inches) across, the mirrorâs massive size is key for seeing in sharp detail. Like in tower and sunshield testing, the Webb team offloaded the weight of both mirrors with cables, pulleys and weights so that they unfolded as if weightless in space.
7. Do Not Disturb
Before a plane takeoff, itâs important for us to turn off our cell phones to make sure that their electromagnetic waves wonât interfere with navigation signals. Similarly, Webb had to test that its scientific instruments wouldnât disrupt the electromagnetic environment of the spacecraft. This way, when we get images back from Webb, weâll know that weâre seeing actual objects in space instead of possible blips caused by electromagnetic interference. These tests took place in the Electromagnetic Interference (EMI) Lab, which looks like a futuristic sound booth! Instead of absorbing sound, however, the walls of this chamber help keep electromagnetic waves from bouncing around.
8. Phoning Earth
How will Webb know where to go and what to look at? Thanks to Webbâs Ground Segment Tests, we know that weâll be able to âtalkâ to Webb after liftoff. In the first six hours after launch, the telescope needs to seamlessly switch between different communication networks and stations located around the world. Flight controllers ran through these complex procedures in fall 2018 to help ensure that launch will be a smooth success.
After Webb reaches its destination, operators will use the Deep Space Network, an international array of giant radio antennas, to relay commands that tell Webb where to look. To test this process when Webb isnât in space yet, the team used special equipment to imitate the real radio link that will exist between the observatory and the network.
9. Hot and Cold
Between 2017 and 2019, Webb engineers separately tested the two halves of the telescope in different thermal vacuum chambers, which are huge, climate-controlled rooms drained of air to match the vacuum of space. In testing, the spacecraft bus and sunshield half were exposed to both boiling hot and freezing cold temperatures, like the conditions that theyâll encounter during Webbâs journey.
But Webbâs mirrors and instruments will need to be colder than cold to operate! This other half of Webb was tested in the historic Chamber A, which was used to test Apollo Moon mission hardware and specifically upgraded to fit Webb. Over about 100 days, Chamber A was gradually cooled down, held at cryogenic temperatures (about minus 387 F, or minus 232.8 C), and then warmed back up to room temperature.
10. Cosmic Vision
When the Hubble Space Telescope was first sent into space, its images were blurry due to a flaw with its mirror. This error taught us about the importance of comprehensively checking Webbâs âeyesâ before the telescope gets out of reach.
Besides training for space survival, Webb also spent time in Chamber A undergoing mirror alignment and optical testing. The team used a piece of test hardware that acted as a source of artificial starlight to verify that light would travel correctly through Webbâs optical system.
Whew! Thatâs a lot of testing under Webbâs belt! Webb is set to launch in October 2021 from Kourou, French Guiana. But until then, itâs still got plenty of training left, including a final round of deployment tests before being shipped to its launch location.
Learn more about the James Webb Space Telescope HERE, or follow the mission on Facebook, Twitter and Instagram.
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Three NASA Telescopes Look at an Angry Young Star Together
Science is a shared endeavor. We learn more when we work together. Today, July 18, weâre using three different space telescopes to observe the same star/planet system!
As our Transiting Exoplanet Survey Satellite (TESS) enters its third year of observations, it's taking a new look at a familiar system this month. And today it won't be alone. Astronomers are looking at AU Microscopii, a young fiery nearby star â about 22 million years old â with the TESS, NICER and Swift observatories.
TESS will be looking for more transits â the passage of a planet across a star â of a recently-discovered exoplanet lurking in the dust of AU Microscopii (called AU Mic for short). Astronomers think there may be other worlds in this active system, as well!
Our Neutron star Interior Composition Explorer (NICER) telescope on the International Space Station will also focus on AU Mic today. While NICER is designed to study neutron stars, the collapsed remains of massive stars that exploded as supernovae, it can study other X-ray sources, too. Scientists hope to observe stellar flares by looking at the star with its high-precision X-ray instrument.
Scientists aren't sure where the X-rays are coming from on AU Mic â it could be from a stellar corona or magnetic hot spots. If it's from hot spots, NICER might not see the planet transit, unless it happens to pass over one of those spots, then it could see a big dip!
A different team of astronomers will use our Neil Gehrels Swift Observatory to peer at AU Mic in X-ray and UV to monitor for high-energy flares while TESS simultaneously observes the transiting planet in the visible spectrum. Stellar flares like those of AU Mic can bathe planets in radiation.
Studying high-energy flares from AU Mic with Swift will help us understand the flare-rate over time, which will help with models of the planetâs atmosphere and the systemâs space weather. There's even a (very) small chance for Swift to see a hint of the planet's transit!
The flares that a star produces can have a direct impact on orbiting planets' atmospheres. The high-energy photons and particles associated with flares can alter the chemical makeup of a planet's atmosphere and erode it away over time.
Another time TESS teamed up with a different spacecraft, it discovered a hidden exoplanet, a planet beyond our solar system called AU Mic b, with the now-retired Spitzer Space Telescope. That notable discovery inspired our latest poster! Itâs free to download in English and Spanish.
Spitzerâs infrared instrument was ideal for peering at dusty systems! Astronomers are still using data from Spitzer to make discoveries. In fact, the James Webb Space Telescope will carry on similar study and observe AU Mic after it launches next year.
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#TBT to 1989 when Voyager 2 spotted Uranus looking like a seemingly perfect robinâs egg. đ⣠⣠When our Voyager 2 spacecraft flew by it in this image, one pole was pointing directly at the Sun. This means that no matter how much it spins, one half is completely in the sun at all times, and the other half is in total darkness.. ⣠⣠Far-flung, Uranus â an ice giant of our solar system â is as mysterious as it is distant. Soon after its launch in 2021, our James Webb Space Telescope will change that by unlocking secrets of its atmosphere. ⣠⣠Image Credit: NASA/JPL-Caltech⣠âŁ
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