Telescope - Blog Posts

monstrous-mind

8 years ago

Astronomy From 45,000 Feet

What is the Stratospheric Observatory for Infrared Astronomy, or SOFIA, up to?

SOFIA, the Stratospheric Observatory for Infrared Astronomy, as our flying telescope is called, is a Boeing 747SP aircraft that carries a 2.5-meter telescope to altitudes as high as 45,000 feet. Researchers use SOFIA to study the solar system and beyond using infrared light. This type of light does not reach the ground, but does reach the altitudes where SOFIA flies.

Recently, we used SOFIA to study water on Venus, hoping to learn more about how that planet lost its oceans. Our researchers used a powerful instrument on SOFIA, called a spectrograph, to detect water in its normal form and “heavy water,” which has an extra neutron. The heavy water takes longer to evaporate and builds up over time. By measuring how much heavy water is on Venus’ surface now, our team will be able to estimate how much water Venus had when the planet formed.

We are also using SOFIA to create a detailed map of the Whirlpool Galaxy by making multiple observations of the galaxy. This map will help us understand how stars form from clouds in that galaxy. In particular, it will help us to know if the spiral arms in the galaxy trigger clouds to collapse into stars, or if the arms just show up where stars have already formed.

We can also use SOFIA to study methane on Mars. The Curiosity rover has detected methane on the surface of Mars. But the total amount of methane on Mars is unknown and evidence so far indicates that its levels change significantly over time and location. We are using SOFIA to search for evidence of this gas by mapping the Red Planet with an instrument specially tuned to sniff out methane.

The plumes, illustrated in the artist’s concept above, were previously seen in images as extensions from the edge of the moon. Next our team will use SOFIA to study Jupiter’s icy moon Europa, searching for evidence of possible water plumes detected by the Hubble Space Telescope. The plumes were previously seen in images as extensions from the edge of the moon. Using SOFIA, we will search for water and determine if the plumes are eruptions of water from the surface. If the plumes are coming from the surface, they may be erupting through cracks in the ice that covers Europa’s oceans. Members of our SOFIA team recently discussed studying Europa on the NASA in Silicon Valley Podcast.

This is the view of Jupiter and its moons taken with SOFIA’s visible light guide camera that is used to position the telescope.

Tags

awesome cool science astronomy sofia telescope

1K notes View Post

nasa

2 months ago

On a jet black background, a bright spiral galaxy softly swirls with sprays of stars extending outward from a small, glowing yellow center. Another galaxy is beneath it and to the left, angling downward. This one is shaped almost like a pea pod with faded tendrils of stars extending from both ends. Together, the pair looks like a rose with the spiral galaxy forming the blossom and the elongated one forming the stem. A handful of large, bright stars speckle the background like sparkles. Credit: NASA, ESA, and G. Bacon, T. Borders, L. Frattare, Z. Levay, and F. Summers (Viz 3D team, STScI)

Love Letters from Space

Love is in the air, and it’s out in space too! The universe is full of amazing chemistry, cosmic couples held together by gravitational attraction, and stars pulsing like beating hearts.

Celestial objects send out messages we can detect if we know how to listen for them. Our upcoming Nancy Grace Roman Space Telescope will help us scour the skies for all kinds of star-crossed signals.

On a backdrop speckled with tiny blue and yellow stars, an enormous heart-shaped nebula looms large. Clumps of dust and gas form intricate shapes, twisting around the edges of the “heart” and appearing to blow off the top in wisps so it almost appears to be on fire. The nebula is deep red and lit from within by a clump of bright blue-white stars. Credit: Brent Newton, used with permission

Celestial Conversation Hearts

Communication is key for any relationship – including our relationship with space. Different telescopes are tuned to pick up different messages from across the universe, and combining them helps us learn even more. Roman is designed to see some visible light – the type of light our eyes can see, featured in the photo above from a ground-based telescope – in addition to longer wavelengths, called infrared. That will help us peer through clouds of dust and across immense stretches of space.

Other telescopes can see different types of light, and some detectors can even help us study cosmic rays, ghostly neutrinos, and ripples in space called gravitational waves.

A complicated conglomeration of stars is intertwined on a black backdrop. Two regions glow pale yellow, one at the lower left of the screen and one at the upper right. Each is surrounded with twisted streams of stars which come together near the center of the frame, making the pair of galaxies look almost like a set of angel wings. The region at the center is dark and dusty, and the galaxies glow blue-white with clumps and speckles of bright pink stars. Credit: NASA, ESA, and the Hubble HeritageTeam (STScI/AURA)-ESA/Hubble Collaboration; Acknowledgment: B. Whitmore (Space Telescope Science Institute)

Intergalactic Hugs

This visible and near-infrared image from the Hubble Space Telescope captures two hearts locked in a cosmic embrace. Known as the Antennae Galaxies, this pair’s love burns bright. The two spiral galaxies are merging together, igniting the birth of brand new baby stars.

Stellar nurseries are often very dusty places, which can make it hard to tell what’s going on. But since Roman can peer through dust, it will help us see stars in their infancy. And Roman’s large view of space coupled with its sharp, deep imaging will help us study how galaxy mergers have evolved since the early universe.

A periodic table of elements titled “Origins of the Elements.” It features the typical boxes and atomic symbols as a usual periodic table, but with pictures inside each indicating how each element is typically forged. A legend at the top explains what each picture means: the big bang, dying low-mass stars, white dwarf supernovae, radioactive decay, cosmic ray collisions, dying high-mass stars, merging neutron stars, and human-made. Credit: NASA’s Goddard Space Flight Center

Cosmic Chemistry

Those stars are destined to create new chemistry, forging elements and scattering them into space as they live, die, and merge together. Roman will help us understand the cosmic era when stars first began forming. The mission will help scientists learn more about how elements were created and distributed throughout galaxies.

Did you know that U and I (uranium and iodine) were both made from merging neutron stars? Speaking of which…

An animation that begins with two glowing white orbs spinning around each other ever faster as they move closer together until they appear to join together. Ripples appear around each of them. When they merge, the animation shifts to a zoomed out view that shows an explosion where two fiery orange jets extend out from the center in opposite directions. At the end of each jet, a large, glowing pink ball extends outward and grows larger, so that the whole thing appears like a giant dumbbell. Credit: NASA’s Goddard Space Flight Center/CI Lab

Fatal Attraction

When two neutron stars come together in a marriage of sorts, it creates some spectacular fireworks! While they start out as stellar sweethearts, these and some other types of cosmic couples are fated for devastating breakups.

When a white dwarf – the leftover core from a Sun-like star that ran out of fuel – steals material from its companion, it can throw everything off balance and lead to a cataclysmic explosion. Studying these outbursts, called type Ia supernovae, led to the discovery that the expansion of the universe is speeding up. Roman will scan the skies for these exploding stars to help us figure out what’s causing the expansion to accelerate – a mystery known as dark energy.

This animation starts with a dim view of the Milky Way, which angles across the screen from the upper left to lower right. A tiny dark ball at the left grows larger as it moves closer until it briefly takes up most of the screen before passing away again to the right. The view shifts to follow its path and we see it as a rotating planet with brownish stripes. As it moves away, the dark world fades into the background. Credit: NASA/JPL-Caltech/R. Hurt (Caltech-IPAC)

Going Solo

Plenty of things in our galaxy are single, including hundreds of millions of stellar-mass black holes and trillions of “rogue” planets. These objects are effectively invisible – dark objects lost in the inky void of space – but Roman will see them thanks to wrinkles in space-time.

Anything with mass warps the fabric of space-time. So when an intervening object nearly aligns with a background star from our vantage point, light from the star curves as it travels through the warped space-time around the nearer object. The object acts like a natural lens, focusing and amplifying the background star’s light.

Thanks to this observational effect, which makes stars appear to temporarily pulse brighter, Roman will reveal all kinds of things we’d never be able to see otherwise.

On a black background, a white outline in the shape of a blocky rainbow contains a picture of a dusty nebula. It’s mottled brown, green, and blue and speckled with glowing pink stars. Channels of dust twist and curl around the edges of the frame, and at the center a small white box contains a much sharper image of part of the nebula. At the top of the blocky rainbow-like outline, it says, “With you, I see the bigger picture,” and underneath it says, “Love, Roman.” Credit: NASA’s Goddard Space Flight Center

Roman is nearly ready to set its sights on so many celestial spectacles. Follow along with the mission’s build progress in this interactive virtual tour of the observatory, and check out these space-themed Valentine’s Day cards.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech valentines day nebula chemistry science nasa galaxies astronomy hubble space telescope stem black holes telescope Roman Space Telescope rogue planets exoplanets

2K notes View Post

nasa

7 months ago

A bowl of homemade swirling, glittery bluish-purple goop: Stardust Slime. The slime fills the bowl, but a portion is being lifted upward as well, highlighting the silver glitter embedded within. Credit: NASA/Ashley Balzer

Launch Your Creativity with Space Crafts!

In honor of the completion of our Nancy Grace Roman Space Telescope’s spacecraft — the vehicle that will maneuver the observatory to its place in space and enable it to function once there — we’re bringing you a space craft you can complete at home! Join us for a journey across the cosmos, starting right in your own pantry.

Stardust Slime

Ingredients:

1 5 oz. bottle clear glue

½ tablespoon baking soda

Food coloring

1 tablespoon contact lens solution

1 tablespoon glitter

Directions:

Pour the glue into a bowl.

Mix in the baking soda.

Add food coloring (we recommend blue, purple, black, or a combination).

Add contact lens solution and use your hands to work it through the slime. It will initially be very sticky! You can add a little extra contact lens solution to make it firmer and less goopy.

Add glitter a teaspoon at a time, using as much or as little as you like!

Did you know that most of your household ingredients are made of stardust? And so are you! Nearly every naturally occurring element was forged by living or dying stars.

Take the baking soda in this slime recipe, for example. It’s made up of sodium, hydrogen, carbon, and oxygen. The hydrogen was made during the big bang, right at the start of the universe. But the other three elements were created by dying stars. So when you show your friends your space-y slime, you can tell them it’s literally made of stardust!

Still feeling crafty? Try your hand at more pantry projects or these 3D and paper spacecraft models. If you’re eager for a more advanced space craft, check out these embroidery creations for inspiration! Or if you’re ready for a break, take a virtual tour of an interactive version of the Roman Space Telescope here.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech crafts diy science nasa astronomy engineering technology stem telescope Roman Space Telescope

1K notes View Post

nasa

8 months ago

25 Years of Exploring the Universe with NASA's Chandra Xray Observatory

Illustration of the Chandra telescope in orbit around Earth. Credit: NASA/CXC & J. Vaughan

On July 23, 1999, the space shuttle Columbia launched into orbit carrying NASA’s Chandra X-ray Observatory. August 26 marked 25 years since Chandra released its first images.

These were the first of more than 25,000 observations Chandra has taken. This year, as NASA celebrates the 25th anniversary of this telescope and the incredible data it has provided, we’re taking a peek at some of its most memorable moments.

About the Spacecraft

The Chandra telescope system uses four specialized mirrors to observe X-ray emissions across the universe. X-rays that strike a “regular” mirror head on will be absorbed, so Chandra’s mirrors are shaped like barrels and precisely constructed. The rest of the spacecraft system provides the support structure and environment necessary for the telescope and the science instruments to work as an observatory. To provide motion to the observatory, Chandra has two different sets of thrusters. To control the temperatures of critical components, Chandra's thermal control system consists of a cooling radiator, insulators, heaters, and thermostats. Chandra's electrical power comes from its solar arrays.

Learn more about the spacecraft's components that were developed and tested at NASA’s Marshall Space Flight Center in Huntsville, Alabama. Fun fact: If the state of Colorado were as smooth as the surface of the Chandra X-ray Observatory mirrors, Pike's Peak would be less than an inch tall.

Engineers in the X-ray Calibration Facility at NASA’s Marshall Space Flight Center in Huntsville, Alabama, integrating the Chandra X-ray Observatory’s High-Resolution Camera with the mirror assembly, in this photo taken March 16, 1997. Credit: NASA

Launch

When space shuttle Columbia launched on July 23, 1999, Chandra was the heaviest and largest payload ever launched by the shuttle. Under the command of Col. Eileen Collins, Columbia lifted off the launch pad at NASA’s Kennedy Space Center in Florida. Chandra was deployed on the mission’s first day.

Reflected in the waters, space shuttle Columbia rockets into the night sky from Launch Pad 39-B on mission STS-93 from Kennedy Space Center. Credit: NASA

First Light Images

Just 34 days after launch, extraordinary first images from our Chandra X-ray Observatory were released. The image of supernova remnant Cassiopeia A traces the aftermath of a gigantic stellar explosion in such captivating detail that scientists can see evidence of what is likely the neutron star.

“We see the collision of the debris from the exploded star with the matter around it, we see shock waves rushing into interstellar space at millions of miles per hour,” said Harvey Tananbaum, founding Director of the Chandra X-ray Center at the Smithsonian Astrophysical Observatory.

Cassiopeia A is the remnant of a star that exploded about 300 years ago. The X-ray image shows an expanding shell of hot gas produced by the explosion colored in bright orange and yellows. Credit: NASA/CXC/SAO

A New Look at the Universe

NASA released 25 never-before-seen views to celebrate the telescopes 25th anniversary. This collection contains different types of objects in space and includes a new look at Cassiopeia A. Here the supernova remnant is seen with a quarter-century worth of Chandra observations (blue) plus recent views from NASA’s James Webb Space Telescope (grey and gold).

This image features deep data of the Cassiopeia A supernova, an expanding ball of matter and energy ejected from an exploding star in blues, greys and golds. The Cassiopeia A supernova remnant has been observed for over 2 million seconds since the start of Chandra’s mission in 1999 and has also recently been viewed by the James Webb Space Telescope. Credit: NASA/CXC/SAO

Can You Hear Me Now?

In 2020, experts at the Chandra X-ray Center/Smithsonian Astrophysical Observatory (SAO) and SYSTEM Sounds began the first ongoing, sustained effort at NASA to “sonify” (turn into sound) astronomical data. Data from NASA observatories such as Chandra, the Hubble Space Telescope, and the James Webb Space Telescope, has been translated into frequencies that can be heard by the human ear.

SAO Research shows that sonifications help many types of learners – especially those who are low-vision or blind -- engage with and enjoy astronomical data more.

Click to watch the “Listen to the Universe” documentary on NASA+ that explores our sonification work: Listen to the Universe | NASA+

An image of the striking croissant-shaped planetary nebula called the Cat’s Eye, with data from the Chandra X-ray Observatory and Hubble Space Telescope. NASA’s Data sonification from Chandra, Hubble and/or Webb telecopes allows us to hear data of cosmic objects. Credit: NASA/CXO/SAO

Celebrate With Us!

Dedicated teams of engineers, designers, test technicians, and analysts at Marshall Space Flight Center in Huntsville, Alabama, are celebrating with partners at the Chandra X-ray Center and elsewhere outside and across the agency for the 25th anniversary of the Chandra X-ray Observatory. Their hard work keeps the spacecraft flying, enabling Chandra’s ongoing studies of black holes, supernovae, dark matter, and more.

Chandra will continue its mission to deepen our understanding of the origin and evolution of the cosmos, helping all of us explore the Universe.

The Chandra Xray Observatory, the longest cargo ever carried to space aboard the space shuttle, is shown in Columbia’s payload bay. This photo of the payload bay with its doors open was taken just before Chandra was tilted upward for release and deployed on July 23, 1999. Credit: NASA

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

Tags

space universe nasa astronomy telescope chandra chandra25

1K notes View Post

nasa

8 months ago

A view into a large clean room, a warehouse-like facility, reveals a set of six large, black rectangular structures that look like circuit boards with red lines and small glass tiles on them. Each panel is flat, installed in a black picture frame structure that allows them to be rotated. In the background, the same type of structures are upright and connected, standing around three times taller than a person. They’re assembled into their stowed, flight-like configuration. Instead of being covered in red circuitry, the upright panels have a series of gray squares all over them that simulate the mass of the solar cells and harnessing. To the upright structure’s right, several workers in head-to-toe white suits and blue gloves stand in a group. Credit: NASA/Chris Gunn

This photo contains both flight (flat in the foreground) and qualification assembly (upright in the background) versions of the Solar Array Sun Shield for NASA’s Nancy Grace Roman Space Telescope. These panels will both shade the mission’s instruments and power the observatory.

Double Vision: Why Do Spacecraft Have Twin Parts?

Seeing double? You’re looking at our Nancy Grace Roman Space Telescope’s Solar Array Sun Shield laying flat in pieces in the foreground, and its test version connected and standing upright in the back. The Sun shield will do exactly what it sounds like –– shade the observatory –– and also collect sunlight for energy to power Roman.

These solar panels are twins, just like several of Roman’s other major components. Only one set will actually fly in space as part of the Roman spacecraft…so why do we need two?

Sometimes engineers do major tests to simulate launch and space conditions on a spare. That way, they don’t risk damaging the one that will go on the observatory. It also saves time because the team can do all the testing on the spare while building up the flight version. In the Sun shield’s case, that means fitting the flight version with solar cells and eventually getting the panels integrated onto the spacecraft.

A series of two images. The top one shows a large metallic structure suspended from the ceiling in a spacious room. The structure is hollow with six sides, each covered with a diamond-like pattern. Three people in head-to-toe white suits and blue gloves watch in the foreground. The left wall in the background is covered in small, pale pink squares. The right wall features a viewing window, through which several observers are looking. The bottom image is a wide-angle view of a similar structure in a different large room. It’s placed at the left end of a giant mechanical arm. Credit: NASA/Jolearra Tshiteya/Chris Gunn (top), NASA/Scott Wiessinger (bottom)

Our Nancy Grace Roman Space Telescope's primary structure (also called the spacecraft bus) moves into the big clean room at our Goddard Space Flight Center (top). While engineers integrate other components onto the spacecraft bus in the clean room, the engineering test unit (also called the structural verification unit) undergoes testing in the centrifuge at Goddard. The centrifuge spins space hardware to ensure it will hold up against the forces of launch.

Engineers at our Goddard Space Flight Center recently tested the Solar Array Sun Shield qualification assembly in a thermal vacuum chamber, which simulates the hot and cold temperatures and low-pressure environment that the panels will experience in space. And since the panels will be stowed for launch, the team practiced deploying them in space-like conditions. They passed all the tests with flying colors!

The qualification panels will soon pass the testing baton to the flight version. After the flight Solar Array Sun Shield is installed on the Roman spacecraft, the whole spacecraft will go through lots of testing to ensure it will hold up during launch and perform as expected in space.

For more information about the Roman Space Telescope, visit: www.nasa.gov/roman. You can also virtually tour an interactive version of the telescope here.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech twins! science nasa astronomy engineering technology stem telescope Roman Space Telescope

1K notes View Post

nasa

9 months ago

Many thousands of galaxies speckle the black screen. The galaxies cluster in the center of the image where they are larger. Several fuzzy yellow galaxies make up the center of the cluster. These galaxies look like soft glowing dust balls, with no defined structure. Hundreds of streaks surround the center of the cluster, as if someone smudged the galaxies’ light in a circular pattern. Thousands of smaller galaxies dot the whole image, like individual specks of dust. These small galaxies vary in size, shape, and color, ranging from red to blue. The different colors are dispersed randomly across the image — there is no apparent patterning or clustering of red or blue galaxies. Credit: NASA, ESA, CSA, STScI

Observations from both NASA’s James Webb and Hubble space telescopes created this colorful image of galaxy cluster MACS0416. The colors of different galaxies indicate distances, with bluer galaxies being closer and redder galaxies being more distant or dusty. Some galaxies appear as streaks due to gravitational lensing — a warping effect caused by large masses gravitationally bending the space that light travels through.

Like Taylor Swift, Our Universe Has Gone Through Many Different Eras

While Taylor's Eras Tour explores decades of music, our universe’s eras set the stage for life to exist today. By unraveling cosmic history, scientists can investigate how it happened, from the universe’s origin and evolution to its possible fate.

A navy blue rectangle forms the background of an infographic. In the top left corner, it says, “History of the Universe.”  An elongated conical shape spans the width of the image. The smaller end of the horn, beginning at a miniscule point, is on the left side of the image and the wider end is on the right. The outline of the horn quickly expands, tracing out the left end of the horn to be about a quarter of the height of the image. The bell shape gradually grows wider as it approaches the right side of the image. The rightmost side of the horn flares outward like a bell. From the left to the right of the horn are 8 ovals that appear to subdivide it. The first oval contains light blue blobs on a dark blue background. Beneath it, it says, “10^-32 seconds, Inflation, initial expansion.” The second oval contains a light blue fog, blue and white orbs, and short, tightly zig-zagged blue lines. Half the white orbs have plus signs, and half have minus signs on them. Beneath the second oval, it says, “1 microsecond, First Particles, neutrons, protons, and electrons form.” The third oval contains a similar blue fog, but the white and blue orbs are stuck to one another in small clusters with no positive or negative signs. The zig-zagged lines remain. Beneath the third oval, it says, “3 minutes, First Nuclei, helium and hydrogen form.” The fourth oval contains a light blue background with some darker blue speckling on it, like on a fresh brown egg. In front of the background are several small spheres. Each sphere is either surrounded by one or two oval outlines. For the spheres with two ovals, the ovals are the same size but are perpendicular to one another. On each oval, in both cases, is a single dot which intersects with the line of the oval as if it traces an orbital. There are still a couple of zig-zagged lines, though much less than in the previous two ovals. Beneath the fourth oval, it says, “380,000 years, First Light, the first atoms form.” The fifth oval contains a blue camouflage-like pattern with a few white dots. Beneath it, it says, “200 million years, First Stars, gas and dust condense into stars.” The sixth oval contains a similar blue camouflage pattern, though it appears to be more transparent. There are several white dots, more than in the fifth oval, and a few white spiral shapes dispersed throughout. Underneath, it says, “400 million years, Galaxies & Dark Matter, galaxies form in dark matter cradles.” In the seventh oval, the blue camouflage pattern has faded, leaving behind a dark blue background with some very thin fog. There are several white dots and white spirals. Beneath the seventh oval, it says, “10 billion years, Dark Energy, expansion accelerates.” The eighth oval is similar to the seventh oval — it features a dark blue background with some thin haze, tens of white dots of varying size, and several spiral shapes of varying size. However, the eighth oval is considerably larger than the rest of the ovals, as it rests at the very end of the flare of the bell shape. Beneath the eighth oval, it says, “13.8 billion years, Today, humans observe the universe.” Credit: NASA

This infographic outlines the history of the universe.

0 SECONDS | In the beginning, the universe debuted extremely small, hot, and dense

Scientists aren’t sure what exactly existed at the very beginning of the universe, but they think there wasn’t any normal matter or physics. Things probably didn’t behave like we expect them to today.

A small flash of white light appears in the middle of a completely black image. The flash expands rapidly, glowing purple and consuming the entire image. The white light shrinks, returning to a pinprick at the center of the image. As it collapses, purple streams and waves pulse outward from the white light’s center. Alongside the waves flow hundreds of small galaxies — spiral and spherical collections of dots of light. The galaxies race out from the center, starting as miniscule specks and becoming larger blobs and smudges as they draw closer, speckling the screen. Credit: NASA’s Goddard Space Flight Center/CI Lab

Artist's interpretation of the beginning of the universe, with representations of the early cosmos and its expansion.

10^-32 SECONDS | The universe rapidly, fearless-ly inflated

When the universe debuted, it almost immediately became unstable. Space expanded faster than the speed of light during a very brief period known as inflation. Scientists are still exploring what drove this exponential expansion.

1 MICROSECOND | Inflation’s end started the story of us: we wouldn’t be here if inflation continued

When inflation ended, the universe continued to expand, but much slower. All the energy that previously drove the rapid expansion went into light and matter — normal stuff! Small subatomic particles — protons, neutrons, and electrons — now floated around, though the universe was too hot for them to combine and form atoms.

The particles gravitated together, especially in clumpy spots. The push and pull between gravity and the particles’ inability to stick together created oscillations, or sound waves.

In front of a dark blue background, hundreds of small red and blue spheres float around, at varying distances from the viewer. In the middle of the screen, two large red and blue spheres collide in the foreground. As they collide, a white flash of light radiates outward. As it fades, the two spheres become visible again, now stuck together. After the first collision, several similar collisions and white flashes are visible in the background. In the top left corner, a clump with one blue sphere and one red sphere races towards another clump with two red spheres and one blue sphere. They collide and there is a flash of white light. As the light clears, a clump with two red spheres and two blue spheres is visible in its place, and a single red sphere floats away toward the center of the screen. Credit: NASA’s Goddard Space Flight Center

Artist's interpretation of protons and neutrons colliding to form ionized deuterium — a hydrogen isotope with one proton and one neutron — and ionized helium — two protons and two neutrons.

THREE MINUTES | Protons and neutrons combined all too well

After about three minutes, the universe had expanded and cooled enough for protons and neutrons to stick together. This created the very first elements: hydrogen, helium, and very small amounts of lithium and beryllium.

But it was still too hot for electrons to combine with the protons and neutrons. These free electrons floated around in a hot foggy soup that scattered light and made the universe appear dark.

In a fuzzy gray fog, hundreds of medium-sized red spheres and small green spheres wiggle around, never moving farther than one diameter from their original position. Hundreds of glowing blue daggers of light bounce between the different spheres, changing direction when they collide with them. Suddenly, the red and green spheres combine, turning brown. The daggers no longer collide with the spheres and instead race away in every direction into open space. A single glowing blue dagger of light zooms away from the spheres and fog into an open blackness speckled with thousands of tiny stars. Credit: NASA/JPL-Caltech

This animated artist’s concept begins by showing ionized atoms (red blobs), free electrons (green blobs), and photons of light (blue flashes). The ionized atoms scattered light until neutral atoms (shown as brown blobs) formed, clearing the way for light to travel farther through space.

380 THOUSAND YEARS | Neutral atoms formed and left a blank space for light

As the universe expanded and cooled further, electrons joined atoms and made them neutral. With the electron plasma out of the way, some light could travel much farther.

A wide oval stretches across a rectangular black background. The oval is about twice as wide as it is tall. It is covered in speckles of varying colors from blue to yellow and red. The colors group together to form large splotches of reds, oranges, and yellows, as well as other splotches of blues and greens. In the bottom left corner, there is a horizontal rectangle with a spectrum of colors, with blue on the left, yellow in the center, and red on the right. Above the rectangle is a label reading “temperature.” Below the rectangle, on the left side under the blue is a label reading, “cooler.” On the right side, under the red, is a label reading “warmer.” Credit: ESA and the Planck Collaboration

An image of the cosmic microwave background (CMB) across the entire sky, taken by ESA's (European Space Agency) Planck space telescope. The CMB is the oldest light we can observe in the universe. Frozen sound waves are visible as miniscule fluctuations in temperature, shown through blue (colder) and red (warmer) coloring.

As neutral atoms formed, the sound waves created by the push and pull between subatomic particles stopped. The waves froze, leaving ripples that were slightly denser than their surroundings. The excess matter attracted even more matter, both normal and “dark.” Dark matter has gravitational influence on its surroundings but is invisible and does not interact with light.

In front of a navy-blue background, tens of light blue orbs float at varying sizes, representing varying distances from the viewer. There are three large blue orbs in the foreground, with small plus signs at their centers. Several yellow streaks of light race across the screen. As the streaks collide with blue orbs, the orbs flash and grow slightly larger, absorbing the yellow streaks, before returning to their original state. The yellow streaks of light do not re-emerge from the orbs. Credit: NASA’s Goddard Space Flight Center

This animation illustrates the absorption of photons — light particles — by neutral hydrogen atoms.

ALSO 380 THOUSAND YEARS | The universe became dark — call it what you want, but scientists call this time period the Dark Ages 

Other than the cosmic microwave background, there wasn't much light during this era since stars hadn’t formed yet. And what light there was usually didn't make it very far since neutral hydrogen atoms are really good at absorbing light. This kicked off an era known as the cosmic dark ages.

A dense orange fog floats in front of a black background that is just barely visible through the thick fog. There are dozens of glowing purple orbs within the fog, clustered in a circle in the center of the visual. One by one, the purple orbs send out bright white circular flashes of light. Following each flash of light, a white ring expands outward from the center of the orb, before fading away once its diameter reaches about one sixth of the image size. Credit: NASA’s Goddard Space Flight Center

This animation illustrates the beginning of star formation as gas begins to clump due to gravity. These protostars heat up as material compresses inside them and throw off material at high speeds, creating shockwaves shown here as expanding rings of light.

200 MILLION YEARS | Stars created daylight (that was still blocked by hydrogen atoms)

Over time, denser areas pulled in more and more matter, in some places becoming so heavy it triggered a collapse. When the matter fell inward, it became hot enough for nuclear fusion to start, marking the birth of the first stars!

In front of a black background, there are millions of glowing green dots. They form a fine, wispy web stretching across the image, like old cobwebs that have collected dust. Over time, more dots collect at the vertices of the web. As the web gets thicker and thicker, the vertices grow and start moving towards each other and towards the center. The smaller dots circle the clumps, like bees buzzing around a hive, until they are pulled inward to join them. Eventually, the clumps merge to create a glowing green mass. The central mass ensnares more dots, coercing even those from the farthest reaches of the screen to circle it. Credit: Simulation: Wu, Hahn, Wechsler, Abel (KIPAC), Visualization: Kaehler (KIPAC)

A simulation of dark matter forming structure due to gravity.

400 MILLION YEARS | Dark matter acted like an invisible string tying galaxies together

As the universe expanded, the frozen sound waves created earlier — which now included stars, gas, dust, and more elements produced by stars — stretched and continued attracting more mass. Pulling material together eventually formed the first galaxies, galaxy clusters, and wide-scale, web-like structure.

A borderless three-dimensional cube rotates from left to right in front of a black background. In the cube are many organic cloud-like blobs. They are primarily purplish blue and black, with the centers being darker than the outsides. In the space between the clouds is a light blue translucent material through which more blobs can be seen further back in the cube. As the cube rotates, the blobs become increasingly red and the blue translucent material becomes increasingly see through. After becoming bright red, the blobs start to fade and become a translucent yellow fog before disappearing completely. As they fade, millions of small yellow-ish stars become visible. The stars dot the cube in every dimension. Credit: M. Alvarez, R. Kaehler and T. Abel

In this animation, ultraviolet light from stars ionizes hydrogen atoms by breaking off their electrons. Regions already ionized are blue and translucent, areas undergoing ionization are red and white, and regions of neutral gas are dark and opaque.

1 BILLION YEARS | Ultraviolet light from stars made the universe transparent for evermore

The first stars were massive and hot, meaning they burned their fuel supplies quickly and lived short lives. However, they gave off energetic ultraviolet light that helped break apart the neutral hydrogen around the stars and allowed light to travel farther.

An animation on a black rectangular background. On the left of the visual is a graph constructed with blue text and the line on the graph. The y-axis of the graph reads “Expansion Speed.” The x-axis is labeled “Time.” At the origin, the x-axis reads, “10 billion years ago.” Halfway across the x-axis is labeled “7 Billion years ago.” At the end of the x-axis is labeled “now.” On the graph is a line which draws itself out. It starts at the top of the y-axis. It slopes down to the right, linearly, as if it were going to draw a straight line from the top left corner of the graph to the bottom right corner of the graph. Around the 7-billion mark, the line begins to decrease in slope very gradually. Three quarters of the way across the x-axis and three quarters of the way down the y-axis, the line reaches a minimum, before quickly curving upwards. It rapidly slopes upward, reaching one quarter from the top of the y-axis as it reaches the end of the x-axis labeled “now.” At the same time, on the right hand of the visual is a tiny dark blue sphere which holds within it glowing lighter blue spheres — galaxies and stars — and a lighter blue webbing. As the line crawls across the graph, the sphere expands. At first, its swelling gently slows, corresponding to the decreasing line on the graph. As the line reaches its minimum and the slope decreases, the sphere slows down its expansion further. Then, as the line arcs back upward, the sphere expands rapidly until it grows larger than the right half of the image and encroaches on the graph. Credit: NASA's Goddard Space Flight Center

Animation showing a graph of the universe’s expansion over time. While cosmic expansion slowed following the end of inflation, it began picking up the pace around 5 billion years ago. Scientists still aren't sure why.

SOMETIME AFTER 10 BILLION YEARS | Dark energy became dominant, accelerating cosmic expansion and creating a big question…?

By studying the universe’s expansion rate over time, scientists made the shocking discovery that it’s speeding up. They had thought eventually gravity should cause the matter to attract itself and slow down expansion. Some mysterious pressure, dubbed dark energy, seems to be accelerating cosmic expansion. About 10 billion years into the universe’s story, dark energy – whatever it may be – became dominant over matter.

A small blue sphere hangs in front of inky blackness. The lower half of the sphere is shrouded in shadow, making it appear hemispherical. The sphere is a rich blue, with swirling white patterns across it — Earth. In the foreground of the image is a gray horizon, covered in small craters and divots — the Moon. Credit: NASA

An image of Earth rising in the Moon’s sky. Nicknamed “Earthrise,” Apollo 8 astronauts saw this sight during the first crewed mission to the Moon.

13.8 BILLION YEARS | The universe as we know it today: 359,785,714,285.7 fortnights from the beginning

We owe our universe today to each of its unique stages. However, scientists still have many questions about these eras.

Our upcoming Nancy Grace Roman Space Telescope will look back in time to explore cosmic mysteries like dark energy and dark matter – two poorly understood aspects of the universe that govern its evolution and ultimate fate.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space Youtube taylor swift the eras tour science nasa astronomy stem telescope cosmology Roman Space Telescope Nancy Grace Roman

2K notes View Post

nasa

1 year ago

Black Scientists and Engineers Past and Present Enable NASA Space Telescope

The Nancy Grace Roman Space Telescope is NASA’s next flagship astrophysics mission, set to launch by May 2027. We’re currently integrating parts of the spacecraft in the NASA Goddard Space Flight Center clean room.

Once Roman launches, it will allow astronomers to observe the universe like never before. In celebration of Black History Month, let’s get to know some Black scientists and engineers, past and present, whose contributions will allow Roman to make history.

Black woman sitting in front of a camera that is slightly off-frame. She is wearing a brown sweater with a white collared shirt underneath. There are images of Earth from space behind her. Credit: NASA

Dr. Beth Brown

The late Dr. Beth Brown worked at NASA Goddard as an astrophysicist. in 1998, Dr. Brown became the first Black American woman to earn a Ph.D. in astronomy at the University of Michigan. While at Goddard, Dr. Brown used data from two NASA X-ray missions – ROSAT (the ROentgen SATellite) and the Chandra X-ray Observatory – to study elliptical galaxies that she believed contained supermassive black holes.

With Roman’s wide field of view and fast survey speeds, astronomers will be able to expand the search for black holes that wander the galaxy without anything nearby to clue us into their presence.

Black-and-white photograph of a Black man standing in front of a chalkboard. He is wearing a dark-colored blazer with a light-colored collared button-up underneath. Credit: courtesy of Georgetown University Archives

Dr. Harvey Washington Banks

In 1961, Dr. Harvey Washington Banks was the first Black American to graduate with a doctorate in astronomy. His research was on spectroscopy, the study of how light and matter interact, and his research helped advance our knowledge of the field. Roman will use spectroscopy to explore how dark energy is speeding up the universe's expansion.

A Black woman stands with her back to the camera and is looking over her shoulder. She is wearing a dark blue jacket that has a white circle outlined image of a plane and the word NASA underneath. She is standing in front of a giant metal circular ring. It sits inside of a large black square box. Credit: NASA/Sydney Rohde

NOTE - Sensitive technical details have been digitally obscured in this photograph.

Sheri Thorn

Aerospace engineer Sheri Thorn is ensuring Roman’s primary mirror will be protected from the Sun so we can capture the best images of deep space. Thorn works on the Deployable Aperture Cover, a large, soft shade known as a space blanket. It will be mounted to the top of the telescope in the stowed position and then deployed after launch. Thorn helped in the design phase and is now working on building the flight hardware before it goes to environmental testing and is integrated to the spacecraft.

A smiling Black woman with shoulder-length straight black hair, glasses, and a white lab coat sits at a blue desk, holding a green circuit board in each hand. She is in a laboratory, and shelves with computer monitors and wires sit behind and around her. A sheet of shiny silver metal stands behind her head, and bags of wires and parts are visible on the desk beside her. Credit: NASA/Katy Comber

Sanetra Bailey

Roman will be orbiting a million miles away at the second Lagrange point, or L2. Staying updated on the telescope's status and health will be an integral part of keeping the mission running. Electronics engineer Sanetra Bailey is the person who is making sure that will happen. Bailey works on circuits that will act like the brains of the spacecraft, telling it how and where to move and relaying information about its status back down to Earth.

Learn more about Sanetra Bailey and her journey to NASA.

A Black man in a clean room wearing a clean suit covering his whole body except his eyes, wearing blue gloves, and holding up a flight detector. Credit: NASA/ Chris Gunn

Dr. Gregory Mosby

Roman’s field of view will be at least 100 times larger than the Hubble Space Telescope's, even though the primary mirrors are the same size. What gives Roman the larger field of view are its 18 detectors. Dr. Gregory Mosby is one of the detector scientists on the Roman mission who helped select the flight detectors that will be our “eyes” to the universe.

Dr. Beth Brown, Dr. Harvey Washington Banks, Sheri Thorn, Sanetra Bailey, and Dr. Greg Mosby are just some of the many Black scientists and engineers in astrophysics who have and continue to pave the way for others in the field. The Roman Space Telescope team promises to continue to highlight those who came before us and those who are here now to truly appreciate the amazing science to come.

A simulated space image with the Roman Space Telescope at the center. It heads toward a purple-and-pink galaxy, and you can see down the barrel opening of the spacecraft. Credit: NASA

To stay up to date on the mission, check out our website and follow Roman on X and Facebook.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

tech science nasa galaxies astronomy astrophysics engineering black history month technology stem black holes telescope Roman Space Telescope BlackExcellence365 space tech spectroscopy

1K notes View Post

nasa

1 year ago

Many thousands of bright stars speckle the screen. The smallest ones are white pinpoints, strewn across the screen like spilled salt. Larger ones are yellow and bluish white with spiky outer edges like sea urchins. Credit: Matthew Penny (Louisiana State University)

A simulated image of NASA’s Nancy Grace Roman Space Telescope’s future observations toward the center of our galaxy, spanning less than 1 percent of the total area of Roman’s Galactic Bulge Time-Domain Survey. The simulated stars were drawn from the Besançon Galactic Model.

Exploring the Changing Universe with the Roman Space Telescope

The view from your backyard might paint the universe as an unchanging realm, where only twinkling stars and nearby objects, like satellites and meteors, stray from the apparent constancy. But stargazing through NASA’s upcoming Nancy Grace Roman Space Telescope will offer a front row seat to a dazzling display of cosmic fireworks sparkling across the sky.

Roman will view extremely faint infrared light, which has longer wavelengths than our eyes can see. Two of the mission’s core observing programs will monitor specific patches of the sky. Stitching the results together like stop-motion animation will create movies that reveal changing objects and fleeting events that would otherwise be hidden from our view.

Watch this video to learn about time-domain astronomy and how time will be a key element in NASA’s Nancy Grace Roman Space Telescope’s galactic bulge survey. Credit: NASA’s Goddard Space Flight Center

This type of science, called time-domain astronomy, is difficult for telescopes that have smaller views of space. Roman’s large field of view will help us see huge swaths of the universe. Instead of always looking at specific things and events astronomers have already identified, Roman will be able to repeatedly observe large areas of the sky to catch phenomena scientists can't predict. Then astronomers can find things no one knew were there!

One of Roman’s main surveys, the Galactic Bulge Time-Domain Survey, will monitor hundreds of millions of stars toward the center of our Milky Way galaxy. Astronomers will see many of the stars appear to flash or flicker over time.

This animation illustrates the concept of gravitational microlensing. When one star in the sky appears to pass nearly in front of another, the light rays of the background source star are bent due to the warped space-time around the foreground star. The closer star is then a virtual magnifying glass, amplifying the brightness of the background source star, so we refer to the foreground star as the lens star. If the lens star harbors a planetary system, then those planets can also act as lenses, each one producing a short change in the brightness of the source. Thus, we discover the presence of each exoplanet, and measure its mass and how far it is from its star. Credit: NASA's Goddard Space Flight Center Conceptual Image Lab

That can happen when something like a star or planet moves in front of a background star from our point of view. Because anything with mass warps the fabric of space-time, light from the distant star bends around the nearer object as it passes by. That makes the nearer object act as a natural magnifying glass, creating a temporary spike in the brightness of the background star’s light. That signal lets astronomers know there’s an intervening object, even if they can’t see it directly.

A galaxy with a large, warmly glowing circular center and several purplish spiral arms extending outward, wrapped around the center like a cinnamon roll. Stars speckle the entire galaxy, but they are most densely packed near the center where they're yellower. Toward the outer edges, the stars are whiter. Overlaid on top of the galaxy is a small pink outline of a spacecraft located a little more than halfway out toward the bottom edge of the galaxy. A reddish search beam extends across the galaxy through its center, about to the same point on the opposite side. Credit: NASA’s Goddard Space Flight Center/CI Lab

This artist’s concept shows the region of the Milky Way NASA’s Nancy Grace Roman Space Telescope’s Galactic Bulge Time-Domain Survey will cover – relatively uncharted territory when it comes to planet-finding. That’s important because the way planets form and evolve may be different depending on where in the galaxy they’re located. Our solar system is situated near the outskirts of the Milky Way, about halfway out on one of the galaxy’s spiral arms. A recent Kepler Space Telescope study showed that stars on the fringes of the Milky Way possess fewer of the most common planet types that have been detected so far. Roman will search in the opposite direction, toward the center of the galaxy, and could find differences in that galactic neighborhood, too.

Using this method, called microlensing, Roman will likely set a new record for the farthest-known exoplanet. That would offer a glimpse of a different galactic neighborhood that could be home to worlds quite unlike the more than 5,500 that are currently known. Roman’s microlensing observations will also find starless planets, black holes, neutron stars, and more!

This animation shows a planet crossing in front of, or transiting, its host star and the corresponding light curve astronomers would see. Using this technique, scientists anticipate NASA’s Nancy Grace Roman Space Telescope could find 100,000 new worlds. Credit: NASA’s Goddard Space Flight Center/Chris Smith (USRA/GESTAR)

Stars Roman sees may also appear to flicker when a planet crosses in front of, or transits, its host star as it orbits. Roman could find 100,000 planets this way! Small icy objects that haunt the outskirts of our own solar system, known as Kuiper belt objects, may occasionally pass in front of faraway stars Roman sees, too. Astronomers will be able to see how much water the Kuiper belt objects have because the ice absorbs specific wavelengths of infrared light, providing a “fingerprint” of its presence. This will give us a window into our solar system’s early days.

A fiery orange globe appears at the left of a white disk of spinning material. As the disk spins, it draws material from the orange globe. Then suddenly the center of the white disk grows extremely bright as a sphere of white blossoms outward. The explosive white sphere then expands, quickly encompassing the whole screen in white criss-crossed with purplish gray filaments. Credit: NASA’s Goddard Space Flight Center/CI

This animation visualizes a type Ia supernova.

Roman’s High Latitude Time-Domain Survey will look beyond our galaxy to hunt for type Ia supernovas. These exploding stars originate from some binary star systems that contain at least one white dwarf – the small, hot core remnant of a Sun-like star. In some cases, the dwarf may siphon material from its companion. This triggers a runaway reaction that ultimately detonates the thief once it reaches a specific point where it has gained so much mass that it becomes unstable.

NASA’s upcoming Nancy Grace Roman Space Telescope will see thousands of exploding stars called supernovae across vast stretches of time and space. Using these observations, astronomers aim to shine a light on several cosmic mysteries, providing a window onto the universe’s distant past. Credit: NASA’s Goddard Space Flight Center

Since these rare explosions each peak at a similar, known intrinsic brightness, astronomers can use them to determine how far away they are by simply measuring how bright they appear. Astronomers will use Roman to study the light of these supernovas to find out how quickly they appear to be moving away from us.

By comparing how fast they’re receding at different distances, scientists can trace cosmic expansion over time. This will help us understand whether and how dark energy – the unexplained pressure thought to speed up the universe’s expansion – has changed throughout the history of the universe.

Left of center, two bright blue circular shapes appear to be joined toward the center of the frame. They are whitest on their outermost edges. Debris, also white and bright blue, emanates outward and extends all around the frame. The background is black. Credit: NASA, ESA, J. Olmsted (STScI)

NASA’s Nancy Grace Roman Space Telescope will survey the same areas of the sky every few days. Researchers will mine this data to identify kilonovas – explosions that happen when two neutron stars or a neutron star and a black hole collide and merge. When these collisions happen, a fraction of the resulting debris is ejected as jets, which move near the speed of light. The remaining debris produces hot, glowing, neutron-rich clouds that forge heavy elements, like gold and platinum. Roman’s extensive data will help astronomers better identify how often these events occur, how much energy they give off, and how near or far they are.

And since this survey will repeatedly observe the same large vista of space, scientists will also see sporadic events like neutron stars colliding and stars being swept into black holes. Roman could even find new types of objects and events that astronomers have never seen before!

Learn more about the exciting science Roman will investigate on X and Facebook.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space Youtube tech stars time galaxy supernova science nasa galaxies astronomy astrophysics technology dark energy black holes telescope cosmology Roman Space Telescope rogue planets exoplanets Nancy Grace Roman space images neutron stars kilonova

2K notes View Post

nasa

1 year ago

Black Hole Friday Deals!

Ad-style comic titled “Black Hole Friday Sales.” Middle of the page “Out-of-this-world deals!” Scattered throughout are illustrated “coupons.” From top to bottom, the taglines read: “Free travel guide to planning your next black hole vacation (when you purchase a cosmic timeshare)”; “Add some planets to your system with this exoplanet bundle!”; “Accretion disk skirt: Be the center of attention. Made of 100% recycled material”; “Standard candles: Reliably bright. Non-scented. Long-lasting burn”; Stephan’s Quintet: A 5-for-1 galactic deal”; “Black hole merger: Get ready to ride this (gravitational) wave before this deal ends”; “Widow system: Act quickly before these stars disappear!”; “Black holes: the perfect (permanent) storage solution”; “Spaghettify! Noodles: Feed the black hole of your stomach”; and “Ready Space Player One. Limited time offer: Roman Space Observer Black Hole DLC! This weekend only!” At the bottom “Get these deals before they disappear beyond the point of no return."

Get these deals before they are sucked into a black hole and gone forever! This “Black Hole Friday,” we have some cosmic savings that are sure to be out of this world.

Your classic black holes — the ultimate storage solution.

Galactic 5-for-1 special! Learn more about Stephan’s Quintet.

Limited-time offer game DLC! Try your hand at the Roman Space Observer Video Game, Black Hole edition, available this weekend only.

Standard candles: Exploding stars that are reliably bright. Multi-functional — can be used to measure distances in space!

Feed the black hole in your stomach. Spaghettification’s on the menu.

Act quickly before the stars in this widow system are gone!

Add some planets to your solar system! Grab our Exoplanet Bundle.

Get ready to ride this (gravitational) wave before this Black Hole Merger ends!

Be the center of attention in this stylish accretion disk skirt. Made of 100% recycled cosmic material.

Should you ever travel to a black hole? No. But if you do, here’s a free guide to make your trip as safe* as possible. *Note: black holes are never safe.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

comic art space comics comic stars galaxy physics science nasa galaxies astronomy astrophysics webb black holes telescope cosmology Hubble Roman Space Telescope exoplanets

3K notes View Post

nasa

1 year ago

Vibrantly hued shapes speckle an image with a black background. Orbs glowing red, yellow, and blue are strewn across the frame, and a large, translucent blue haze dominates most of the center. Credit: NASA, ESA, and M. Brodwin (University of Missouri)

Astronomers used three of NASA's Great Observatories to capture this multiwavelength image showing galaxy cluster IDCS J1426.5+3508. It includes X-rays recorded by the Chandra X-ray Observatory in blue, visible light observed by the Hubble Space Telescope in green, and infrared light from the Spitzer Space Telescope in red. This rare galaxy cluster has important implications for understanding how these megastructures formed and evolved early in the universe.

How Astronomers Time Travel

Let’s add another item to your travel bucket list: the early universe! You don’t need the type of time machine you see in sci-fi movies, and you don’t have to worry about getting trapped in the past. You don’t even need to leave the comfort of your home! All you need is a powerful space-based telescope.

But let’s start small and work our way up to the farthest reaches of space. We’ll explain how it all works along the way.

This animation shows a small, blue planet Earth at the left of the frame and an even smaller white dot representing the Moon at the right. The background is black. A beam of light travels back and forth between them. The graphic is labeled “Earth and Moon to scale, Speed of light in real-time, surface-to-surface in 1.255 seconds, average distance 384,400 km.” Credit: James O'Donoghue, used with permission

This animation illustrates how fast light travels between Earth and the Moon. The farther light has to travel, the more noticeable its speed limit becomes.

The speed of light is superfast, but it isn’t infinite. It travels at about 186,000 miles (300 million meters) per second. That means that it takes time for the light from any object to reach our eyes. The farther it is, the more time it takes.

You can see nearby things basically in real time because the light travel time isn’t long enough to make a difference. Even if an object is 100 miles (161 kilometers) away, it takes just 0.0005 seconds for light to travel that far. But on astronomical scales, the effects become noticeable.

The Sun and planets are lined up along the center of the frame with distances shown to scale. The title is “The Solar System: with real-time speed of light.” Earth is labeled 1 AU, 8 minutes 17 seconds; Jupiter is 5.2 AU, 43 minutes 17 seconds; Saturn is 9.6 AU, 1 hour 20 minutes; Uranus is 19.2 AU, 2 hours 40 minutes; and Neptune is 30 AU, 4 hours 10 minutes. The bottom of the graphic says, “1 AU (astronomical unit) = 93 million miles, or 150 million kilometers.” Credit: James O'Donoghue, used with permission

This infographic shows how long it takes light to travel to different planets in our solar system.

Within our solar system, light’s speed limit means it can take a while to communicate back and forth between spacecraft and ground stations on Earth. We see the Moon, Sun, and planets as they were slightly in the past, but it's not usually far enough back to be scientifically interesting.

As we peer farther out into our galaxy, we use light-years to talk about distances. Smaller units like miles or kilometers would be too overwhelming and we’d lose a sense of their meaning. One light-year – the distance light travels in a year – is nearly 6 trillion miles (9.5 trillion kilometers). And that’s just a tiny baby step into the cosmos.

The Sun’s closest neighboring star, Proxima Centauri, is 4.2 light-years away. That means we see it as it was about four years ago. Betelgeuse, a more distant (and more volatile) stellar neighbor, is around 700 light-years away. Because of light’s lag time, astronomers don’t know for sure whether this supergiant star is still there! It may have already blasted itself apart in a supernova explosion – but it probably has another 10,000 years or more to go.

$An undulating, translucent star-forming region in the Carina Nebula, hued in ambers and blues. Foreground stars with diffraction spikes can be seen, as can a speckling of background points of light through the cloudy nebula. Credit: NASA, ESA, CSA, and STScI$

What looks much like craggy mountains on a moonlit evening is actually the edge of a nearby, young, star-forming region NGC 3324 in the Carina Nebula. Captured in infrared light by the Near-Infrared Camera (NIRCam) on NASA’s James Webb Space Telescope, this image reveals previously obscured areas of star birth.

The Carina Nebula clocks in at 7,500 light-years away, which means the light we receive from it today began its journey about 3,000 years before the pyramids of Giza in Egypt were built! Many new stars there have undoubtedly been born by now, but their light may not reach Earth for thousands of years.

Glowing spiral arms are twisted around like a cosmic cinnamon roll. A bright yellow oval is diagonal in the center of the frame, and sprays of stars extend outward from it like tentacles. Pink, white, and blue stars speckle the spiral arms and dusty lanes lie in between. The glowing arms are streaked with smaller clumps of dust. Credit: NASA and Nick Risinger

An artist’s concept of our Milky Way galaxy, with rough locations for the Sun and Carina nebula marked.

If we zoom way out, you can see that 7,500 light-years away is still pretty much within our neighborhood. Let’s look further back in time…

$Spiral galaxy NGC 5643 with a bright, barred center surrounded by an orange-y glow. Vaguely purplish swirling arms extend outward from the center and appear somewhat mottled as streams of dust block white and blue stars in the arms here and there. A few stars are each surrounded by many sharp diffraction spikes. Credit: ESA/Hubble and NASA, A. Riess et al.; acknowledgement: Mahdi Zamani$

This stunning image by the NASA/ESA Hubble Space Telescope features the spiral galaxy NGC 5643. Looking this good isn’t easy; 30 different exposures, for a total of nine hours of observation time, together with Hubble’s high resolution and clarity, were needed to produce an image of such exquisite detail and beauty.

Peering outside our Milky Way galaxy transports us much further into the past. The Andromeda galaxy, our nearest large galactic neighbor, is about 2.5 million light-years away. And that’s still pretty close, as far as the universe goes. The image above shows the spiral galaxy NGC 5643, which is about 60 million light-years away! That means we see it as it was about 60 million years ago.

As telescopes look deeper into the universe, they capture snapshots in time from different cosmic eras. Astronomers can stitch those snapshots together to unravel things like galaxy evolution. The closest ones are more mature; we see them nearly as they truly are in the present day because their light doesn’t have to travel as far to reach us. We can’t rewind those galaxies (or our own), but we can get clues about how they likely developed. Looking at galaxies that are farther and farther away means seeing these star cities in ever earlier stages of development.

The farthest galaxies we can see are both old and young. They’re billions of years old now, and the light we receive from them is ancient since it took so long to traverse the cosmos. But since their light was emitted when the galaxies were young, it gives us a view of their infancy.

The animation begins with a tiny dot of purplish light which quickly explodes, with a flash of light blossoming out to cover the whole frame. The light subsides and the screen shows galaxies of smudgy or spiral shapes racing outward from the center of the frame. Credit: NASA’s Goddard Space Flight Center

This animation is an artist’s concept of the big bang, with representations of the early universe and its expansion.

Comparing how fast objects at different distances are moving away opened up the biggest mystery in modern astronomy: cosmic acceleration. The universe was already expanding as a result of the big bang, but astronomers expected it to slow down over time. Instead, it’s speeding up!

The universe’s expansion makes it tricky to talk about the distances of the farthest objects. We often use lookback time, which is the amount of time it took for an object’s light to reach us. That’s simpler than using a literal distance, because an object that was 10 billion light-years away when it emitted the light we received from it would actually be more than 16 billion light-years away right now, due to the expansion of space. We can even see objects that are presently over 30 billion light-years from Earth, even though the universe is only about 14 billion years old.

$Hundreds of red, yellow, white, and blue galaxies are sprinkled across a black background, appearing as small, brightly colored smudges. The tiniest galaxies appear as mere dots, while larger ones are disk-shaped. One blue star with six diffraction spikes shines in the lower-left corner. Credit: NASA, ESA, CSA, and M. Zamani (ESA/Webb). Science: B. Robertson (UCSC), S. Tacchella (Cambridge), E. Curtis-Lake (Hertfordshire), S. Carniani (Scuola Normale Superiore), and the JADES Collaboration$

This James Webb Space Telescope image shines with the light from galaxies that are more than 13.4 billion years old, dating back to less than 400 million years after the big bang.

Our James Webb Space Telescope has helped us time travel back more than 13.4 billion years, to when the universe was less than 400 million years old. When our Nancy Grace Roman Space Telescope launches in a few years, astronomers will pair its vast view of space with Webb’s zooming capabilities to study the early universe in better ways than ever before. And don’t worry – these telescopes will make plenty of pit stops along the way at other exciting cosmic destinations across space and time.

Learn more about the exciting science Roman will investigate on X and Facebook.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

Youtube stars galaxy nasa galaxies astronomy astrophysics webb dark energy telescope cosmology Hubble Roman Space Telescope chandra space images Spitzer

3K notes View Post

nasa

1 year ago

Hot New Planetary System Just Dropped.

We hope you like your planetary systems extra spicy. 🔥

A new system of seven sizzling planets has been discovered using data from our retired Kepler space telescope.

Named Kepler-385, it’s part of a new catalog of planet candidates and multi-planet systems discovered using Kepler.

The discovery helps illustrate that multi-planetary systems have more circular orbits around the host star than systems with only one or two planets.

Our Kepler mission is responsible for the discovery of the most known exoplanets to date. The space telescope’s observations ended in 2018, but its data continues to paint a more detailed picture of our galaxy today.

Here are a few more things to know about Kepler-385:

Artist’s concept of Kepler 385, a seven-planet system with a Sun-like star to the left of the image and the planets varying in color and size are arranged in a straight line from inner-most to outer-most going from left to right. Credit: NASA/Daniel Rutter

All seven planets are between the size of Earth and Neptune.

Artist’s concept showing two of the seven planets discovered orbiting a Sun-like star. Credit: NASA/Daniel Rutter

Its star is 10% larger and 5% hotter than our Sun.

This artist concept shows NASA's planet-hunting Kepler spacecraft among the stars. The spacecraft looks like a golden cylinder with one end cut diagonally. Silver metal surrounds the cylinder, with solar panels all along one portion. Credit: NASA/ESA/CSA/STScI

This system is one of over 700 that Kepler’s data has revealed.

The planets’ orbits have been represented in sound.

Now that you’ve heard a little about this planetary system, get acquainted with more exoplanets and why we want to explore them.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space Youtube tech universe nasa kepler technology telescope exoplanets space telescope data sonification sounds of space space sounds

3K notes View Post

nasa

1 year ago

A group of people wearing white clean room suits with hoods and blue gloves work in a circle at the base of a tall, silver-and-gold structure laced with wiring. Behind them, on the right, is an eight-story white wall with blue stripes and a glass window. The left, far wall is covered in pale, square filters. Credit: NASA/Chris Gunn

The Nancy Grace Roman Space Telescope’s flight harness is transferred from the mock-up structure to the spacecraft flight structure.

Your Body is Wired Like a NASA Space Telescope. Sort Of.

If our Nancy Grace Roman Space Telescope were alive, its nervous system would be the intricate wiring, or “harness,” that helps different parts of the observatory communicate with one another. Just like the human body sends information through nerves to function, Roman will send commands through this special harness to help achieve its mission: answering longstanding questions about dark energy, dark matter, and exoplanets, among other mind-bending cosmic queries.

Roman’s harness weighs around 1,000 pounds and is made of about 32,000 wires and 900 connectors. If those parts were laid out end-to-end, they would be 45 miles long from start to finish. Coincidentally, the human body’s nerves would span the same distance if lined up. That’s far enough to reach nearly three-fourths of the way to space, twice as far as a marathon, or eight times taller than Mount Everest!

Seen from above, two individuals wearing white clean room suits with hoods and blue gloves work inside of a large, silvery metal structure with a hexagonal shape and a large cylindrical hole, covered in a diamond-patterned texture. Red and white wire bundles of cables drape across the top of the structure like strands of spaghetti. Credit: NASA/Chris Gunn

An aerial view of the harness technicians working to secure Roman’s harness to the spacecraft flight structure.

Over a span of two years, 11 technicians spent time at the workbench and perched on ladders, cutting wire to length, carefully cleaning each component, and repeatedly connecting everything together.

Space is usually freezing cold, but spacecraft that are in direct sunlight can get incredibly hot. Roman’s harness went through the Space Environment Simulator – a massive thermal vacuum chamber – to expose the components to the temperatures they’ll experience in space. Technicians “baked” vapors out of the harness to make sure they won’t cause problems later in orbit.

Seen from below, two individuals wearing white clean room suits with hoods and blue gloves work inside of a silvery cylindrical metal structure. Seven bright lights mounted to the ceiling shine down onto them. Credit: NASA/Chris Gunn

Technicians work to secure Roman’s harness to the interior of the spacecraft flight structure. They are standing in the portion of the spacecraft bus where the propellant tanks will be mounted.

The next step is for engineers to weave the harness through the flight structure in Goddard’s big clean room, a space almost perfectly free of dust and other particles. This process will be ongoing until most of the spacecraft components are assembled. The Roman Space Telescope is set to launch by May 2027.

Learn more about the exciting science this mission will investigate on X and Facebook.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech universe nasa astronomy engineering dark matter technology dark energy telescope Roman Space Telescope space hardware

4K notes View Post

nasa

1 year ago

In this multiwavelength image, the central object resembles a semi-transparent, spinning toy top in shades of purple and magenta against a black background. The top-like structure appears to be slightly falling toward the right side of the image. At its center is a bright spot. This is the pulsar that powers the nebula. A stream of material is spewing forth from the pulsar in a downward direction, constituting what would be the part of a top that touches a surface while it is spinning. Wispy purple light accents regions surrounding the object. This image combines data from NASA's Chandra, Hubble, and Spitzer telescopes. Credit: X-ray: NASA/CXC/SAO; Optical: NASA/STScI; Infrared: NASA-JPL-Caltech

Navigating Deep Space by Starlight

On August 6, 1967, astrophysicist Jocelyn Bell Burnell noticed a blip in her radio telescope data. And then another. Eventually, Bell Burnell figured out that these blips, or pulses, were not from people or machines.

This photograph shows astrophysicist Jocelyn Bell Burnell smiling into a camera. She is wearing glasses, a pink collared shirt, and a black cardigan. She is holding a yellow pencil above a piece of paper with a red line across it. There is a tan lampshade and several books in the background. The image is watermarked “Copyright: Robin Scagell/Galaxy Picture Library.”

The blips were constant. There was something in space that was pulsing in a regular pattern, and Bell Burnell figured out that it was a pulsar: a rapidly spinning neutron star emitting beams of light. Neutron stars are superdense objects created when a massive star dies. Not only are they dense, but neutron stars can also spin really fast! Every star we observe spins, and due to a property called angular momentum, as a collapsing star gets smaller and denser, it spins faster. It’s like how ice skaters spin faster as they bring their arms closer to their bodies and make the space that they take up smaller.

This animation depicts a distant pulsar blinking amidst a dark sky speckled with colorful stars and other objects. The pulsar is at the center of the image, glowing purple, varying in brightness and intensity in a pulsating pattern. As the camera pulls back, we see more surrounding objects, but the pulsar continues to blink. The image is watermarked “Artist’s concept.” Credit: NASA’s Goddard Space Flight Center

The pulses of light coming from these whirling stars are like the beacons spinning at the tops of lighthouses that help sailors safely approach the shore. As the pulsar spins, beams of radio waves (and other types of light) are swept out into the universe with each turn. The light appears and disappears from our view each time the star rotates.

A small neutron star spins at the center of this animation. Two purple beams of light sweep around the star-filled sky, emanating from two spots on the surface of the neutron star, and one beam crosses the viewer’s line of sight with a bright flash. The image is watermarked “Artist’s concept.” Credit: NASA's Goddard Space Flight Center.

After decades of studying pulsars, astronomers wondered—could they serve as cosmic beacons to help future space explorers navigate the universe? To see if it could work, scientists needed to do some testing!

First, it was important to gather more data. NASA’s NICER, or Neutron star Interior Composition Explorer, is a telescope that was installed aboard the International Space Station in 2017. Its goal is to find out things about neutron stars like their sizes and densities, using an array of 56 special X-ray concentrators and sensitive detectors to capture and measure pulsars’ light.

This time-lapse of our Neutron star Interior Composition Explorer (NICER) shows how it scans the skies to study pulsars and other X-ray sources from its perch aboard the International Space Station. NICER is near the center of the image, a white box mounted on a platform with a shiny panel on one side and dozens of cylindrical mirrors on the opposite side. Around it are other silver and white instruments and scaffolding. NICER swivels and pans to track objects, and some other objects nearby move as well. The station’s giant solar panels twist and turn in the background. Movement in the sequence, which represents a little more than one 90-minute orbit, is sped up by 100 times. Credit: NASA.

But how can we use these X-ray pulses as navigational tools? Enter SEXTANT, or Station Explorer for X-ray Timing and Navigation Technology. If NICER was your phone, SEXTANT would be like an app on it.

During the first few years of NICER’s observations, SEXTANT created an on-board navigation system using NICER’s pulsar data. It worked by measuring the consistent timing between each pulsar’s pulses to map a set of cosmic beacons.

This photo shows the NICER payload on the International Space Station. Against a black background, tall rectangular solar panels that appear as a golden mesh rise from the bottom of the photo, passing through its middle area. In front of that are a variety of gray and white shapes that make up instruments and the structure of the space station near NICER. Standing above from them, attached to a silver pole, is the rectangular box of the NICER telescope, which is pointing its concentrators up and to the right. Credit: NASA.

When calculating position or location, extremely accurate timekeeping is essential. We usually rely on atomic clocks, which use the predictable fluctuations of atoms to tick away the seconds. These atomic clocks can be located on the ground or in space, like the ones on GPS satellites. However, our GPS system only works on or close to Earth, and onboard atomic clocks can be expensive and heavy. Using pulsar observations instead could give us free and reliable “clocks” for navigation. During its experiment, SEXTANT was able to successfully determine the space station’s orbital position!

A photo of the International Space Station as seen from above. The left and right sides of the image are framed by the station's long, rectangular solar panels, with a complex array of modules and hardware in the middle. The background is taken up fully by the surface of the Earth; lakes, snow-capped mountains, and a large body of water are faintly visible beneath white clouds. Credit: NASA

We can calculate distances using the time taken for a signal to travel between two objects to determine a spacecraft’s approximate location relative to those objects. However, we would need to observe more pulsars to pinpoint a more exact location of a spacecraft. As SEXTANT gathered signals from multiple pulsars, it could more accurately derive its position in space.

This animation shows how triangulating the distances to multiple pulsars could help future space explorers determine their location. In the first sequence, the location of a spaceship is shown in a blue circle in the center of the image against a dark space background. Three pulsars, shown as spinning beams of light, appear around the location. They are circled in green and then connected with dotted lines. Text on screen reads “NICER data are also used in SEXTANT, an on-board demonstration of pulsar-based navigation.” The view switches to the inside of a futuristic spacecraft, looking through the windshield at the pulsars. An illuminated control panel glows in blues and purples. On-screen text reads “This GPS-like technology may revolutionize deep space navigation through the solar system and beyond.” Credit: NASA’s Johnson Space Center

So, imagine you are an astronaut on a lengthy journey to the outer solar system. You could use the technology developed by SEXTANT to help plot your course. Since pulsars are reliable and consistent in their spins, you wouldn’t need Wi-Fi or cell service to figure out where you were in relation to your destination. The pulsar-based navigation data could even help you figure out your ETA!

NASA’s Space Launch System (SLS) rocket carrying the Orion spacecraft launched on the Artemis I flight test. With Artemis I, NASA sets the stage for human exploration into deep space, where astronauts will build and begin testing the systems near the Moon needed for lunar surface missions and exploration to other destinations farther from Earth. This image shows a SLS rocket against a dark, evening sky and clouds of smoke coming out from the launch pad. This is all reflected on the water in the foreground of the photo. Credit: NASA/Bill Ingalls

None of these missions or experiments would be possible without Jocelyn Bell Burnell’s keen eye for an odd spot in her radio data decades ago, which set the stage for the idea to use spinning neutron stars as a celestial GPS. Her contribution to the field of astrophysics laid the groundwork for research benefitting the people of the future, who yearn to sail amongst the stars.

Keep up with the latest NICER news by following NASA Universe on X and Facebook and check out the mission’s website. For more on space navigation, follow @NASASCaN on X or visit NASA’s Space Communications and Navigation website.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space star universe deep space science nasa astronomy navigation telescope spaceblr pulsar Jocelyn Bell Burnell neutron star

3K notes View Post

nasa

2 years ago

Caution: Universe Work Ahead 🚧

We only have one universe. That’s usually plenty – it’s pretty big after all! But there are some things scientists can’t do with our real universe that they can do if they build new ones using computers.

The universes they create aren’t real, but they’re important tools to help us understand the cosmos. Two teams of scientists recently created a couple of these simulations to help us learn how our Nancy Grace Roman Space Telescope sets out to unveil the universe’s distant past and give us a glimpse of possible futures.

Caution: you are now entering a cosmic construction zone (no hard hat required)!

A black square covered in thousands of tiny red dots and thousands more slightly larger, white and yellow fuzzy blobs. Each speck is a simulated galaxy. Credit: M. Troxel and Caltech-IPAC/R. Hurt

This simulated Roman deep field image, containing hundreds of thousands of galaxies, represents just 1.3 percent of the synthetic survey, which is itself just one percent of Roman's planned survey. The full simulation is available here. The galaxies are color coded – redder ones are farther away, and whiter ones are nearer. The simulation showcases Roman’s power to conduct large, deep surveys and study the universe statistically in ways that aren’t possible with current telescopes.

One Roman simulation is helping scientists plan how to study cosmic evolution by teaming up with other telescopes, like the Vera C. Rubin Observatory. It’s based on galaxy and dark matter models combined with real data from other telescopes. It envisions a big patch of the sky Roman will survey when it launches by 2027. Scientists are exploring the simulation to make observation plans so Roman will help us learn as much as possible. It’s a sneak peek at what we could figure out about how and why our universe has changed dramatically across cosmic epochs.

This video begins by showing the most distant galaxies in the simulated deep field image in red. As it zooms out, layers of nearer (yellow and white) galaxies are added to the frame. By studying different cosmic epochs, Roman will be able to trace the universe's expansion history, study how galaxies developed over time, and much more.

As part of the real future survey, Roman will study the structure and evolution of the universe, map dark matter – an invisible substance detectable only by seeing its gravitational effects on visible matter – and discern between the leading theories that attempt to explain why the expansion of the universe is speeding up. It will do it by traveling back in time…well, sort of.

Seeing into the past

Looking way out into space is kind of like using a time machine. That’s because the light emitted by distant galaxies takes longer to reach us than light from ones that are nearby. When we look at farther galaxies, we see the universe as it was when their light was emitted. That can help us see billions of years into the past. Comparing what the universe was like at different ages will help astronomers piece together the way it has transformed over time.

The animation starts with a deep field image of the universe, showing warm toned galaxies as small specks dusted on a black backdrop. Then the center is distorted as additional layers of galaxies are added. The center appears to bulge toward the viewer, and galaxies are enlarged and smeared into arcs. Credit: Caltech-IPAC/R. Hurt

This animation shows the type of science that astronomers will be able to do with future Roman deep field observations. The gravity of intervening galaxy clusters and dark matter can lens the light from farther objects, warping their appearance as shown in the animation. By studying the distorted light, astronomers can study elusive dark matter, which can only be measured indirectly through its gravitational effects on visible matter. As a bonus, this lensing also makes it easier to see the most distant galaxies whose light they magnify.

The simulation demonstrates how Roman will see even farther back in time thanks to natural magnifying glasses in space. Huge clusters of galaxies are so massive that they warp the fabric of space-time, kind of like how a bowling ball creates a well when placed on a trampoline. When light from more distant galaxies passes close to a galaxy cluster, it follows the curved space-time and bends around the cluster. That lenses the light, producing brighter, distorted images of the farther galaxies.

Roman will be sensitive enough to use this phenomenon to see how even small masses, like clumps of dark matter, warp the appearance of distant galaxies. That will help narrow down the candidates for what dark matter could be made of.

Three small squares filled with bluish dots emerge from a black screen. The black background is then filled with bluish dots too, and then the frame zooms out to see a much larger area of the dots. Credit: NASA's Goddard Space Flight Center and A. Yung

In this simulated view of the deep cosmos, each dot represents a galaxy. The three small squares show Hubble's field of view, and each reveals a different region of the synthetic universe. Roman will be able to quickly survey an area as large as the whole zoomed-out image, which will give us a glimpse of the universe’s largest structures.

Constructing the cosmos over billions of years

A separate simulation shows what Roman might expect to see across more than 10 billion years of cosmic history. It’s based on a galaxy formation model that represents our current understanding of how the universe works. That means that Roman can put that model to the test when it delivers real observations, since astronomers can compare what they expected to see with what’s really out there.

A cone shaped assortment of blue dots is on a grid. The tip of the cone is labeled "present day," and the other end is labeled "13.4 billion years ago." Three slices from the middle are pulled out and show the universe's structure developing over time. Credit: NASA's Goddard Space Flight Center and A. Yung

In this side view of the simulated universe, each dot represents a galaxy whose size and brightness corresponds to its mass. Slices from different epochs illustrate how Roman will be able to view the universe across cosmic history. Astronomers will use such observations to piece together how cosmic evolution led to the web-like structure we see today.

This simulation also shows how Roman will help us learn how extremely large structures in the cosmos were constructed over time. For hundreds of millions of years after the universe was born, it was filled with a sea of charged particles that was almost completely uniform. Today, billions of years later, there are galaxies and galaxy clusters glowing in clumps along invisible threads of dark matter that extend hundreds of millions of light-years. Vast “cosmic voids” are found in between all the shining strands.

Astronomers have connected some of the dots between the universe’s early days and today, but it’s been difficult to see the big picture. Roman’s broad view of space will help us quickly see the universe’s web-like structure for the first time. That’s something that would take Hubble or Webb decades to do! Scientists will also use Roman to view different slices of the universe and piece together all the snapshots in time. We’re looking forward to learning how the cosmos grew and developed to its present state and finding clues about its ultimate fate.

Thousands of small, light and deep blue dots cover a black background representing galaxies in a simulated universe. A tiny white square is labeled "Hubble." A set of 18 much larger squares, oriented in three curved rows, are labeled "Roman." Credit: NASA's Goddard Space Flight Center and A. Yung

This image, containing millions of simulated galaxies strewn across space and time, shows the areas Hubble (white) and Roman (yellow) can capture in a single snapshot. It would take Hubble about 85 years to map the entire region shown in the image at the same depth, but Roman could do it in just 63 days. Roman’s larger view and fast survey speeds will unveil the evolving universe in ways that have never been possible before.

Roman will explore the cosmos as no telescope ever has before, combining a panoramic view of the universe with a vantage point in space. Each picture it sends back will let us see areas that are at least a hundred times larger than our Hubble or James Webb space telescopes can see at one time. Astronomers will study them to learn more about how galaxies were constructed, dark matter, and much more.

The simulations are much more than just pretty pictures – they’re important stepping stones that forecast what we can expect to see with Roman. We’ve never had a view like Roman’s before, so having a preview helps make sure we can make the most of this incredible mission when it launches.

Learn more about the exciting science this mission will investigate on Twitter and Facebook.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

stars galaxy nasa galaxies astronomy astrophysics dark matter webb telescope cosmology Hubble spaceblr Roman Space Telescope

1K notes View Post

nasa

2 years ago

Our Roman Space Telescope’s Dish is Complete!

Wide shot of the Nancy Grace Roman Space Telescope’s high-gain antenna inside a testing chamber that is covered in blue spiked-shaped foam. The antenna is a large grey dish, about the height of a refrigerator, facing slightly to the left. There is a small circle that is elevated in the middle of the antenna disk by six metal strips. The antenna is mounted to a base that is also covered in blue spikes. Credit: NASA/Chris Gunn

NASA engineers recently completed tests of the high-gain antenna for our Nancy Grace Roman Space Telescope. This observatory has some truly stellar plans once it launches by May 2027. Roman will help unravel the secrets of dark energy and dark matter – two invisible components that helped shape our universe and may determine its ultimate fate. The mission will also search for and image planets outside our solar system and explore all kinds of other cosmic topics.

However, it wouldn’t be able to send any of the data it will gather back to Earth without its antenna. Pictured above in a test chamber, this dish will provide the primary communication link between the Roman spacecraft and the ground. It will downlink the highest data volume of any NASA astrophysics mission so far.

Close-up of the Nancy Grace Roman Space Telescope’s high-gain antenna inside a testing chamber that is covered in blue spiked-shaped foam. The antenna is a large grey dish, about the height of a refrigerator, facing slightly to the right. There is a small circle that is elevated in the middle of the antenna disk by six metal strips. There are small faint black circles that cover the disk. Credit: NASA/Chris Gunn

The antenna reflector is made of a carbon composite material that weighs very little but will still withstand wide temperature fluctuations. It’s very hot and cold in space – Roman will experience a temperature range of minus 26 to 284 degrees Fahrenheit (minus 32 to 140 degrees Celsius)!

The dish spans 5.6 feet (1.7 meters) in diameter, standing about as tall as a refrigerator, yet only weighs 24 pounds (10.9 kilograms) – about as much as a dachshund. Its large size will help Roman send radio signals across a million miles of intervening space to Earth.

At one frequency, the dual-band antenna will receive commands and send back information about the spacecraft’s health and location. It will use another frequency to transmit a flood of data at up to 500 megabits per second to ground stations on Earth. The dish is designed to point extremely accurately at Earth, all while both Earth and the spacecraft are moving through space.

Close-up of the spiked-shaped blue foam covering the walls of the chamber. Credit: NASA/Chris Gunn

Engineers tested the antenna to make sure it will withstand the spacecraft’s launch and operate as expected in the extreme environment of space. The team also measured the antenna’s performance in a radio-frequency anechoic test chamber. Every surface in the test chamber is covered in pyramidal foam pieces that minimize interfering reflections during testing. Next, the team will attach the antenna to the articulating boom assembly, and then electrically integrate it with Roman’s Radio Frequency Communications System.

Learn more about the exciting science this mission will investigate on Twitter and Facebook.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech nasa astronomy engineering dark matter technology dark energy telescope Roman Space Telescope space hardware

1K notes View Post

nasa

2 years ago

Say Hello to NGC 6441

A crowded cluster of over a million stars packs together at the center of this image of the star cluster NGC 6441. These stars shine in white, red, blue, and yellowish hues, and grow more sporadic at the image’s edges, all glittering against a black backdrop of space. Credit: ESA/Hubble & NASA, G. Piotto

Location: In the Scorpius constellation

Distance from Earth: About 44,000 light-years

Object type: Globular star cluster

Discovered by: James Dunlop in 1826

Each tiny point of light in this image is its own star - and there are more than a million of them! This stunning image captured by the Hubble Telescope depicts NGC 6441, a globular cluster that weighs about 1.6 million times the mass of our Sun. Globular clusters like NGC 6441 are groups of old stars held together by their mutual gravitational attraction, appearing nearly spherical in shape due to the density of stars that comprises them. This particular cluster is one of the most massive and luminous in our Milky Way Galaxy. It is also home to a planetary nebula and four pulsars (rotating neutron stars that emit beams of radiation at steady intervals, detected when the beams are aimed at Earth).

Read more information about NGC 6441 here.

Right now, the Hubble Space Telescope is delving into its #StarrySights campaign! Find more star cluster content and spectacular new images by following along on Hubble’s Twitter, Facebook, and Instagram.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space stars universe science nasa astronomy cosmos telescope Hubble

2K notes View Post

nasa

2 years ago

A Laboratory for Star Formation

Alt text: In this image of NGC 3603, a bright cluster of stars shining in red, orange, and yellow hues dominates the center. The stars become more sporadic throughout the rest of the image, glittering against a black backdrop of space and nebulous indigo clouds that glow in the picture’s lower half.

Credit: NASA, ESA, R. O'Connell (University of Virginia), F. Paresce (National Institute for Astrophysics, Bologna, Italy), E. Young (Universities Space Research Association/Ames Research Center), the WFC3 Science Oversight Committee, and the Hubble Heritage Team (STScI/AURA)

Location: In the Carina spiral arm of our Milky Way Galaxy

Distance from Earth: About 20,000 light-years

Object type: Nebula and open star cluster

Discovered by: Sir John Herschel in 1834

Imaged here by the Hubble Space Telescope, NGC 3603 is a collection of thousands of large, hot stars, including some of the most massive stars known to us. Scientists categorize it as an “open cluster” because of its spread-out shape and low density of stars. Surrounding the bright star cluster are plumes of interstellar gas and dust, which comprise the nebula part of this cosmic object. New stars are formed from the gaseous material within these clouds! NGC 3603 holds stars at a variety of life stages, making it a laboratory for scientists to study star evolution and formation. Astronomers estimate that star formation in and around the cluster has been occurring for 10 to 20 million years.

Read more information about NGC 3603 here.

Right now, the Hubble Space Telescope is delving into its #StarrySights campaign! Find more star cluster content and breathtaking new images by following along on Hubble’s Twitter, Facebook, and Instagram.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space stars universe science nasa astronomy cosmos telescope Hubble spaceblr

1K notes View Post

nasa

2 years ago

A Dusty Fingerprint in Space

An image from NASA’s James Webb Space Telescope shows a bright dot at the center of star-filled black space. The bright dot is actually two stars meeting, as their orbits bring them together every 8 years. The stellar pair are surrounded by 17 rings of gas and dust that appear orangish gray. The rings have a slight rectangular shape and are very clear and defined starting at about 1 o’clock on a clockface. The rings start to break up a bit to our view traveling clockwise around the image. As you arrive at the 12:40 position, only parts of about six rings can be seen as they disappear from view.

A new image from NASA's James Webb Space Telescope reveals a remarkable cosmic sight: at least 17 concentric dust rings emanating from a pair of stars. Just 5,300 light-years from Earth, the star duo are collectively known as Wolf-Rayet 140. Each ring was created when the two stars came close together and their stellar winds (streams of gas they blow into space) collided so forcefully that some of the gas was compressed into dust. The stars' orbits bring them together about once every eight years, and forms a half-shell of dust that looks like a ring from our perspective. Like a cosmic fingerprint, the 17 rings reveal more than a century of stellar interactions—and the "fingerprint" belonging to Wolf-Rayet 140 may be equally unique. Other Wolf-Rayet stars produce dust, but no other pair are known to produce rings quite like Wolf-Rayet 140.

Learn more about Wolf-Rayet 140.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

stars universe nasa astronomy telescope spaceblr Webb Telescope

14K notes View Post

nasa

2 years ago

Why Do X-Ray Mirrors Look So Unusual?

Completed quadrant of an X-ray Mirror Assembly, under development for the JAXA/NASA XRISM mission. It is shaped like a fan with thin metal struts holding it together.

Does the object in this image look like a mirror? Maybe not, but that’s exactly what it is! To be more precise, it’s a set of mirrors that will be used on an X-ray telescope. But why does it look nothing like the mirrors you’re familiar with? To answer that, let’s first take a step back. Let’s talk telescopes.

How does a telescope work?

The basic function of a telescope is to gather and focus light to amplify the light’s source. Astronomers have used telescopes for centuries, and there are a few different designs. Today, most telescopes use curved mirrors that magnify and focus light from distant objects onto your eye, a camera, or some other instrument. The mirrors can be made from a variety of materials, including glass or metal.

Diagram showing a reflecting telescope with a pair of mirrors to focus the light on the detector — in this case, an observer’s eye. The diagram shows the “flow” of light, which starts at a distant galaxy, enters the telescope and bounces off the primary mirror at the bottom of the telescope. Then the light moves to the secondary mirror which redirects the light out of the side of the telescope tube into the observer’s eye.

Space telescopes like the James Webb and Hubble Space Telescopes use large mirrors to focus light from some of the most distant objects in the sky. However, the mirrors must be tailored for the type and range of light the telescope is going to capture—and X-rays are especially hard to catch.

X-rays versus mirrors

X-rays tend to zip through most things. This is because X-rays have much smaller wavelengths than most other types of light. In fact, X-rays can be smaller than a single atom of almost every element. When an X-ray encounters some surfaces, it can pass right between the atoms!

X-ray image of a human elbow. Denser materials, like bone, stop more X-rays than skin and muscle.

Doctors use this property of X-rays to take pictures of what’s inside you. They use a beam of X-rays that mostly passes through skin and muscle but is largely blocked by denser materials, like bone. The shadow of what was blocked shows up on the film.

This tendency to pass through things includes most mirrors. If you shoot a beam of X-rays into a standard telescope, most of the light would go right through or be absorbed. The X-rays wouldn’t be focused by the mirror, and we wouldn’t be able to study them.

Animation first showing a plane of balls face-on and an arrow passing through the space between the balls. Then the angle changes to show the balls edge-on and an arrow bouncing off the top.

X-rays can bounce off a specially designed mirror, one turned on its side so that the incoming X-rays arrive almost parallel to the surface and glance off it. At this shallow angle, the space between atoms in the mirror's surface shrinks so much that X-rays can't sneak through. The light bounces off the mirror like a stone skipping on water. This type of mirror is called a grazing incidence mirror.

A metallic onion

Telescope mirrors curve so that all of the incoming light comes to the same place. Mirrors for most telescopes are based on the same 3D shape — a paraboloid. You might remember the parabola from your math classes as the cup-shaped curve. A paraboloid is a 3D version of that, spinning it around the axis, a little like the nose cone of a rocket. This turns out to be a great shape for focusing light at a point.

A line drawing of a parabola - a cup-shaped curve, shown here on its side - spins around to create a 3D shape. The word “paraboloid” shows on the screen. Then part of the curve fades away, leaving behind two things: a small concave circle, which was one end of the paraboloid, labeled “Radio dishes; optical, infrared and ultraviolet telescope mirrors,” and a cylinder with sloping walls, which was the part of the edges of the paraboloid, labeled “X-ray mirrors.”

Mirrors for visible and infrared light and dishes for radio light use the “cup” portion of that paraboloid. For X-ray astronomy, we cut it a little differently to use the wall. Same shape, different piece. The mirrors for visible, infrared, ultraviolet, and radio telescopes look like a gently-curving cup. The X-ray mirror looks like a cylinder with very slightly angled walls.

The image below shows how different the mirrors look. On the left is one of the Chandra X-ray Observatory’s cylindrical mirrors. On the right you can see the gently curved round primary mirror for the Stratospheric Observatory for Infrared Astronomy telescope.

On the left, a technician stands next to a cylinder-shaped mirror designed for X-ray astronomy. The mirror is held in a frame a little off the ground, and is about as tall as the technician. On the right, two technicians inspect a round mirror for optical astronomy.

If we use just one grazing incidence mirror in an X-ray telescope, there would be a big hole, as shown above (left). We’d miss a lot of X-rays! Instead, our mirror makers fill in that cylinder with layers and layers of mirrors, like an onion. Then we can collect more of the X-rays that enter the telescope, giving us more light to study.

Completed X-ray Mirror Assembly for the X-ray Imaging and Spectroscopy Mission (XRISM, pronounced “crism”), which is a collaboration between the Japan Aerospace Exploration Agency (JAXA) and NASA, along with ESA participation. The assembly has thin metal struts fanning outward from a silver ring in the center of the image. Shiny ridge surfaces (actually many thin mirrors!) fill in the spaces between the struts.

Nested mirrors like this have been used in many X-ray telescopes. Above is a close-up of the mirrors for an upcoming observatory called the X-ray Imaging and Spectroscopy Mission (XRISM, pronounced “crism”), which is a Japan Aerospace Exploration Agency (JAXA)-led international collaboration between JAXA, NASA, and the European Space Agency (ESA).

The XRISM mirror assembly uses thin, gold-coated mirrors to make them super reflective to X-rays. Each of the two assemblies has 1,624 of these layers packed in them. And each layer is so smooth that the roughest spots rise no more than one millionth of a millimeter.

Chandra observations of the Perseus galaxy cluster showing turbulence in the hot X-ray-emitting gas.

Why go to all this trouble to collect this elusive light? X-rays are a great way to study the hottest and most energetic areas of the universe! For example, at the centers of certain galaxies, there are black holes that heat up gas, producing all kinds of light. The X-rays can show us light emitted by material just before it falls in.

Stay tuned to NASA Universe on Twitter and Facebook to keep up with the latest on XRISM and other X-ray observatories.

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech universe nasa astronomy astrophysics technology x ray telescope spaceblr chandra XRISM x-ray vision

1K notes View Post

nasa

3 years ago

Spread your cosmic wings 🦋

The Butterfly Nebula, created by a dying star, was captured by the Hubble Space Telescope in this spectacular image. Observations were taken over a more complete spectrum of light, helping researchers better understand the “wings'' of gas bursting out from its center. The nebula’s dying central star has become exceptionally hot, shining ultraviolet light brightly over the butterfly’s wings and causing the gas to glow.

Learn more about Hubble’s celebration of Nebula November and see new nebula images, here.

You can also keep up with Hubble on Twitter, Instagram, Facebook, and Flickr!

Image credits: NASA, ESA, and J. Kastner (RIT)

Tags

artists on tumblr space stars universe butterflies nebula photographers on tumblr science nasa astronomy wallpapers cosmos telescope Hubble nebula november

3K notes View Post

nasa

3 years ago

The stunning Veil Nebula was created after a star about 20 times the mass of the Sun lived fast and died young – exploding in a cataclysmic release of energy known as a supernova.

In a violent stellar explosion roughly 10,000 years ago, shockwaves and debris created this staggeringly beautiful trail through space. The picture above shows a mosaic of six Hubble Space Telescope pictures, a small area roughly two light-years across, and only a tiny fraction of the nebula's vast 110 light-year structure.

To learn more about Hubble’s celebration of Nebula November and see new nebula images, visit our space telescope's nebula page.

You can also keep up with Hubble on Twitter, Instagram, Facebook, and Flickr!

Image credits: NASA, ESA, and the Hubble Heritage Team (STScI/AURA)

Tags

artists on tumblr space universe outer space nebula supernova photographers on tumblr nasa astronomy cosmos telescope Hubble nebula november

2K notes View Post

nasa

3 years ago

Roman’s Heat-Vision Eyes Are Complete!

Our Nancy Grace Roman Space Telescope team recently flight-certified all 24 of the detectors the mission needs. When Roman launches in the mid-2020s, the detectors will convert starlight into electrical signals, which will then be decoded into 300-megapixel images of huge patches of the sky. These images will help astronomers explore all kinds of things, from rogue planets and black holes to dark matter and dark energy.

Eighteen of the detectors will be used in Roman’s camera, while another six will be reserved as backups. Each detector has 16 million tiny pixels, so Roman’s images will be super sharp, like Hubble’s.

The image above shows one of Roman’s detectors compared to an entire cell phone camera, which looks tiny by comparison. The best modern cell phone cameras can provide around 12-megapixel images. Since Roman will have 18 detectors that have 16 million pixels each, the mission will capture 300-megapixel panoramas of space.

The combination of such crisp resolution and Roman’s huge view has never been possible on a space-based telescope before and will make the Nancy Grace Roman Space Telescope a powerful tool in the future.

Learn more about the Roman Space Telescope!

Make sure to follow us on Tumblr for your regular dose of space!

Tags

space tech stars universe planets photography nasa galaxies space photography engineering solar system technology telescope exploration Roman Space Telescope space telescope space technology camera day

1K notes View Post

nasa

4 years ago

The Great Conjunction of Jupiter and Saturn

Credits: NASA/Bill Ingalls

Have you noticed two bright objects in the sky getting closer together with each passing night? It’s Jupiter and Saturn doing a planetary dance that will result in the Great Conjunction on Dec. 21. On that day, Jupiter and Saturn will be right next to each other in the sky – the closest they have appeared in nearly 400 years!

Skywatching Tips from NASA

Credits: NASA/JPL-Caltech

For those who would like to see this phenomenon for themselves, here’s what to do:

Find a spot with an unobstructed view of the sky, such as a field or park. Jupiter and Saturn are bright, so they can be seen even from most cities.

An hour after sunset, look to the southwestern sky. Jupiter will look like a bright star and be easily visible. Saturn will be slightly fainter and will appear slightly above and to the left of Jupiter until December 21, when Jupiter will overtake it and they will reverse positions in the sky.

The planets can be seen with the unaided eye, but if you have binoculars or a small telescope, you may be able to see Jupiter’s four large moons orbiting the giant planet.

How to Photograph the Conjunction

Credits: NASA/Bill Dunford

Saturn and Jupiter are easy to see without special equipment, and can be photographed easily on DSLR cameras and many cell phone cameras. Here are a few tips and tricks:

These planets are visible in the early evening, and you'll have about 1-2 hours from when they are visible, to when they set. A photo from the same location can look completely different just an hour later!

Using a tripod will help you hold your camera steady while taking longer exposures. If you don’t have a tripod, brace your camera against something – a tree, a fence, or a car can all serve as a tripod for a several-second exposure.

The crescent Moon will pass near Jupiter and Saturn a few days before the conjunction. Take advantage of it in your composition!

Get more tips HERE.

Still have questions about the Great Conjunction?

Our NASA expert answered questions from social media on an episode of NASA Science Live on Thursday, Dec. 17. Watch the recording HERE.

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com.

Tags

space photography nasa saturn... astronomy jupiter christmas star telescope great conjunction

3K notes View Post

nasa

5 years ago

Celebrating Spitzer, One of NASA’s Great Observatories

As the Spitzer Space Telescope’s 16-year mission ends, we’re celebrating the legacy of our infrared explorer. It was one of four Great Observatories – powerful telescopes also including Hubble, Chandra and Compton – designed to observe the cosmos in different parts of the electromagnetic spectrum.

Light our eyes can see

The part of the spectrum we can see is called, predictably, visible light. But that’s just a small segment of all the wavelengths of the spectrum. The Hubble Space Telescope observes primarily in the visible spectrum. Our Chandra X-ray Observatory is designed to detect (you guessed it) X-ray emissions from very hot regions of the universe, like exploded stars and matter around black holes. Our Compton Gamma Ray Observatory, retired in 2000, produced the first all-sky survey in gamma rays, the most energetic and penetrating form of light.

Celebrating Spitzer, One Of NASA’s Great Observatories

Then there’s infrared…

Infrared radiation, or infrared light, is another type of energy that we can't see but can feel as heat. All objects in the universe emit some level of infrared radiation, whether they're hot or cold. Spitzer used its infrared instrument to make discoveries in our solar system (including Saturn's largest ring) all the way to the edge of the universe. From stars being born to planets beyond our solar system (like the seven Earth-size exoplanets around the star TRAPPIST-1), Spitzer's science discoveries will continue to inspire the world for years to come.

Multiple wavelengths

Together, the work of the Great Observatories gave us a more complete view and understanding of our universe.

Hubble and Chandra will continue exploring our universe, and next year they’ll be joined by an even more powerful observatory … the James Webb Space Telescope!

Many of Spitzer's breakthroughs will be studied more precisely with the Webb Space Telescope. Like Spitzer, Webb is specialized for infrared light. But with its giant gold-coated beryllium mirror and nine new technologies, Webb is about 1,000 times more powerful. The forthcoming telescope will be able to push Spitzer's science findings to new frontiers, from identifying chemicals in exoplanet atmospheres to locating some of the first galaxies to form after the Big Bang.

We can’t wait for another explorer to join our space telescope superteam!

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

Tags

space stars universe nebula science nasa galaxies big bang telescope teamwork Spitzer space pictures spitzer space telescope legands

1K notes View Post

nasa

5 years ago

Celebrate #BlackHoleFriday with Nurturing Baby Stars

Are you throwing all your money into a black hole today?

Forget Black Friday — celebrate #BlackHoleFriday with us and get sucked into this recent discovery of a black hole that may have sparked star births across multiple galaxies.

If confirmed, this discovery would represent the widest reach ever seen for a black hole acting as a stellar kick-starter — enhancing star formation more than one million light-years away. (One light year is equal to 6 trillion miles.)

A black hole is an extremely dense object from which no light can escape. The black hole's immense gravity pulls in surrounding gas and dust. Sometimes, black holes hinder star birth. Sometimes — like perhaps in this case — they increase star birth.

Telescopes like our Chandra X-ray Observatory help us detect the X-rays produced by hot gas swirling around the black hole. Have more questions about black holes? Click here to learn more.

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com.

Tags

space star universe galaxy nasa astronomy black friday stellar x ray BLACK HOLE telescope blackholefriday star birth

1K notes View Post

nasa

5 years ago

5 of Your Fermi Gamma-ray Space Telescope Questions Answered

The Fermi Gamma-ray Space Telescope is a satellite in low-Earth orbit that detects gamma rays from exotic objects like black holes, neutron stars and fast-moving jets of hot gas. For 11 years Fermi has seen some of the highest-energy bursts of light in the universe and is helping scientists understand where gamma rays come from.

Confused? Don’t be! We get a ton of questions about Fermi and figured we'd take a moment to answer a few of them here.

1. Who was this Fermi guy?

The Fermi telescope was named after Enrico Fermi in recognition of his work on how the tiny particles in space become accelerated by cosmic objects, which is crucial to understanding many of the objects that his namesake satellite studies.

Enrico Fermi was an Italian physicist and Nobel Prize winner (in 1938) who immigrated to the United States to be a professor of physics at Columbia University, later moving to the University of Chicago.

Original image courtesy Argonne National Laboratory

Over the course of his career, Fermi was involved in many scientific endeavors, including the Manhattan Project, quantum theory and nuclear and particle physics. He even engineered the first-ever atomic reactor in an abandoned squash court (squash is the older, English kind of racquetball) at the University of Chicago.

There are a number of other things named after Fermi, too: Fermilab, the Enrico Fermi Nuclear Generating Station, the Enrico Fermi Institute and more. (He’s kind of a big deal in the physics world.)

Fermi even had something to say about aliens! One day at lunch with his buddies, he wondered if extraterrestrial life existed outside our solar system, and if it did, why haven't we seen it yet? His short conversation with friends sparked decades of research into this idea and has become known as the Fermi Paradox — given the vastness of the universe, there is a high probability that alien civilizations exist out there, so they should have visited us by now.

2. So, does the Fermi telescope look for extraterrestrial life?

No. Although both are named after Enrico Fermi, the Fermi telescope and the Fermi Paradox have nothing to do with one another.

Fermi does not look for aliens, extraterrestrial life or anything of the sort! If aliens were to come our way, Fermi would be no help in identifying them, and they might just slip right under Fermi’s nose. Unless, of course, those alien spacecraft were powered by processes that left behind traces of gamma rays.

Fermi detects gamma rays, the highest-energy form of light, which are often produced by events so far away the light can take billions of years to reach Earth. The satellite sees pulsars, active galaxies powered by supermassive black holes and the remnants of exploding stars. These are not your everyday stars, but the heavyweights of the universe.

3. Does the telescope shoot gamma rays?

No. Fermi DETECTS gamma rays using its two instruments, the Large Area Telescope (LAT) and the Gamma-ray Burst Monitor (GBM).

The LAT sees about one-fifth of the sky at a time and records gamma rays that are millions of times more energetic than visible light. The GBM detects lower-energy emissions, which has helped it identify more than 2,000 gamma-ray bursts – energetic explosions in galaxies extremely far away.

The highest-energy gamma ray from a gamma-ray burst was detected by Fermi’s LAT, and traveled 3.8 billion light-years to reach us from the constellation Leo.

4. Will gamma rays turn me into a superhero?

Nope. In movies and comic books, the hero has a tragic backstory and a brush with death, only to rise out of some radioactive accident stronger and more powerful than before. In reality, that much radiation would be lethal.

In fact, as a form of radiation, gamma rays are dangerous for living cells. If you were hit with a huge amount of gamma radiation, it could be deadly — it certainly wouldn’t be the beginning of your superhero career.

5. That sounds bad…does that mean if a gamma-ray burst hit Earth, it would wipe out the planet and destroy us all?

Thankfully, our lovely planet has an amazing protector from gamma radiation: an atmosphere. That is why the Fermi telescope is in orbit; it’s easier to detect gamma rays in space!

Gamma-ray bursts are so far away that they pose no threat to Earth. Fermi sees gamma-ray bursts because the flash of gamma rays they release briefly outshines their entire home galaxies, and can sometimes outshine everything in the gamma-ray sky.

If a habitable planet were too close to one of these explosions, it is possible that the jet emerging from the explosion could wipe out all life on that planet. However, the probability is extremely low that a gamma-ray burst would happen close enough to Earth to cause harm. These events tend to occur in very distant galaxies, so we’re well out of reach.

We hope that this has helped to clear up a few misconceptions about the Fermi Gamma-ray Space Telescope. It’s a fantastic satellite, studying the craziest extragalactic events and looking for clues to unravel the mysteries of our universe!

Now that you know the basics, you probably want to learn more! Follow the Fermi Gamma-ray Space Telescope on Twitter (@NASAFermi) or Facebook (@nasafermi), and check out more awesome stuff on our Fermi webpage.

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com.

Tags

space star universe light science nasa EXPLOSION BLACK HOLE telescope beam pulsar Fermi discoveries gamma ray fermi paradox

1K notes View Post

nasa

6 years ago

The James Webb Space Telescope: Art + Science Continuing to Inspire

The James Webb Space Telescope – our next infrared space observatory – will not only change what we know, but also how we think about the night sky and our place in the cosmos. This epic mission to travel back in time to look back at the first stars and galaxies has inspired artists from around the world to create art inspired by the mission.

Image Credit: Anri Demchenko

It’s been exactly two years since the opening of the first James Webb Space Telescope Art + Science exhibit at the NASA Goddard Visitor Center. The exhibit was full of pieces created by artists who had the special opportunity to visit Goddard and view the telescope in person in late 2016.

Online Submission Image Credit: Tina Saramaga

Since the success of the event and exhibit, the Webb project has asked its followers to share any art they have created that was inspired by the mission. They have received over 125 submissions and counting!

Image Credit: Enrico Novelli

Online Submission Image Credit: Unni Isaksen

A selection of these submissions will be on display at NASA Goddard’s Visitor Center from now until at least the end of April 2019. The artists represented in this exhibit come not just from around the country, but from around the world, showing how art and science together can bring a love of space down to Earth.

More information about each piece in the exhibit can be found in our web gallery. Want to participate and share your own art? Tag your original art, inspired by the James Webb Space Telescope, on Twitter or Instagram with #JWSTArt, or email us through our website! For more info and rules, see: http://nasa.gov/jwstart.

Webb is the work of hands and minds from across the planet. We’re leading this international project with our partners from the European Space Agency (ESA) and the Canadian Space Agency (CSA), and we’re all looking forward to its launch in 2021. Once in space, Webb will solve mysteries of our solar system, look beyond to distant worlds around other stars, and probe the mysterious structures and origins of our universe and our place in it.

Learn more about the James Webb Space Telescope HERE, or follow the mission on Facebook, Twitter and Instagram.

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

Tags

art space stars science space art nasa galaxies JWST james webb telescope space telescope nasa goddard

1K notes View Post

nasa

6 years ago

Five Facts About the Kepler Space Telescope That Will Blow You Away!

Ten years ago, on March 6, 2009, a rocket lifted off a launch pad at Cape Canaveral Air Force Station in Florida. It carried a passenger that would revolutionize our understanding of our place in the cosmos--NASA’s first planet hunter, the Kepler space telescope. The spacecraft spent more than nine years in orbit around the Sun, collecting an unprecedented dataset for science that revealed our galaxy is teeming with planets. It found planets that are in some ways similar to Earth, raising the prospects for life elsewhere in the cosmos, and stunned the world with many other first-of-a-kind discoveries. Here are five facts about the Kepler space telescope that will blow you away:

Kepler observed more than a half million stars looking for planets beyond our solar system.

It discovered more than 2,600 new worlds…

…many of which could be promising places for life.

Kepler’s survey revealed there are more planets than stars in our galaxy.

The spacecraft is now drifting around the Sun more than 94 million miles away from Earth in a safe orbit.

NASA retired the Kepler spacecraft in 2018. But to this day, researchers continue to mine its archive of data, uncovering new worlds.

*All images are artist illustrations. Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

Tags

space sun star galaxy science earth nasa planet kepler telescope spacecraft exoplanet

2K notes View Post

nasa

6 years ago

Why Do Some Galactic Unions Lead to Doom?

Three images from our Spitzer Space Telescope show pairs of galaxies on the cusp of cosmic consolidations. Though the galaxies appear separate now, gravity is pulling them together, and soon they will combine to form new, merged galaxies. Some merged galaxies will experience billions of years of growth. For others, however, the merger will kick off processes that eventually halt star formation, dooming the galaxies.

Only a few percent of galaxies in the nearby universe are merging, but galaxy mergers were more common between 6 billion and 10 billion years ago, and these processes profoundly shaped our modern galactic landscape. Scientists study nearby galaxy mergers and use them as local laboratories for that earlier period in the universe's history. The survey has focused on 200 nearby objects, including many galaxies in various stages of merging.

Merging galaxies in the nearby universe appear especially bright to infrared observatories like Spitzer. In these images, different colors correspond to different wavelengths of infrared light, which are not visible to the human eye. Blue corresponds to 3.6 microns, and green corresponds to 4.5 microns - both strongly emitted by stars. Red corresponds to 8.0 microns, a wavelength mostly emitted by dust.

Tags

space star gravity galaxy science nasa telescope

1K notes View Post

nasa

6 years ago

Our Favorite Valentines Throughout the Universe

Today is Valentine’s Day. What better way to express that you love someone than with an intergalactic love gram? Check out some of our favorites and send them to all of your cosmic companions:

Your love is galactic

The Hubble Space Telescope revolutionized nearly all areas of astronomical research — and captured some truly lovely images. Here, a pair of intersecting galaxies swirl into the shape of a rose as a result of gravitational tidal pull. What type of roses are you getting for your love — red or galactic?

I think you’re n{ice}

IceBridge is the largest airborne survey of Earth’s polar ice ever flown. It captures 3-D views of Arctic and Antarctic ice sheets, ice shelves and sea ice. This lovely heart-shaped glacier feature was discovered in northwest Greenland during an IceBridge flight in 2017. Which of your lover’s features would you say are the coolest?

You’re absolutely magnetic

Even though we can't see them, magnetic fields are all around us. One of the solar system’s largest magnetospheres belongs to Jupiter. Right now, our Juno spacecraft is providing scientists with their first glimpses of this unseen force. Is your attraction to your loved one magnetic?

You’re MARS-velous

This heart-shaped feature on the Martian landscape was captured by our Mars Reconnaissance Orbiter. It was created by a small impact crater that blew darker material on the surface away. What impact has your loved one had on you?

I <3 you

From three billion miles away, Pluto sent a “love note” back to Earth, via our New Horizons spacecraft. This stunning image of Pluto's "heart" shows one of the world's most dominant features, estimated to be 1,000 miles (1,600 km) across at its widest point. Will you pass this love note on to someone special in your life?

Light of my life

Our Solar Dynamics Observatory keeps an eye on our closest star that brings energy to you and your love. The observatory helps us understand where the Sun's energy comes from, how the inside of the Sun works, how energy is stored and released in the Sun's atmosphere and much more. Who would you say is your ray of sunshine?

Do any of these cosmic phenomena remind you of someone in your universe? Download these cards here to send to all the stars in your sky.

Want something from the Red Planet to match your bouquet of red roses? Here is our collection of Martian Valentines.

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

Tags

love space sun galaxy earth nasa jupiter pluto mars valentinesday solar system telescope

4K notes View Post