I Sit And Watch You...

i sit and watch you...

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!

2K notes View Post

taylorswift-iraqifan

2 months ago

5 Unpredictable Things Swift Has Studied (and 1 It’s Still Looking For)

Our Neil Gehrels Swift Observatory — Swift for short — is celebrating its 20th anniversary! The satellite studies cosmic objects and events using visible, ultraviolet, X-ray, and gamma-ray light. Swift plays a key role in our efforts to observe our ever-changing universe. Here are a few cosmic surprises Swift has caught over the years — plus one scientists hope to see.

This sequence shows X-rays from the initial flash of GRB 221009A that could be detected for weeks as dust in our galaxy scattered the light back to us. This resulted in the appearance of an extraordinary set of expanding rings, here colored magenta, with a bright yellow spot at the center. The images were captured over 12 days by the X-ray Telescope aboard NASA’s Neil Gehrels Swift Observatory. Credit: NASA/Swift/A. Beardmore (University of Leicester)

#BOAT

Swift was designed to detect and study gamma-ray bursts, the most powerful explosions in the universe. These bursts occur all over the sky without warning, with about one a day detected on average. They also usually last less than a minute – sometimes less than a few seconds – so you need a telescope like Swift that can quickly spot and precisely locate these new events.

In the fall of 2022, for example, Swift helped study a gamma-ray burst nicknamed the BOAT, or brightest of all time. The image above depicts X-rays Swift detected for 12 days after the initial flash. Dust in our galaxy scattered the X-ray light back to us, creating an extraordinary set of expanding rings.

This gif illustrates what happens when an unlucky star strays too close to a monster black hole. Gravitational forces create intense tides that break the star apart into a stream of gas. The trailing part of the stream escapes the system, while the leading part swings back around, surrounding the black hole with a disk of debris. This cataclysmic phenomenon is called a tidal disruption event. This image is watermarked “Artist’s concept.” Credit: NASA’s Goddard Space Flight Center/Chris Smith (USRA/GESTAR)

Star meets black hole

Tidal disruptions happen when an unlucky star strays too close to a black hole. Gravitational forces break the star apart into a stream of gas, as seen above. Some of the gas escapes, but some swings back around the black hole and creates a disk of debris that orbits around it.

These events are rare. They only occur once every 10,000 to 100,000 years in a galaxy the size of our Milky Way. Astronomers can’t predict when or where they’ll pop up, but Swift’s quick reflexes have helped it observe several tidal disruption events in other galaxies over its 20-year career.

This gif illustrates various features of a galaxy's outburst. The black hole in the center is surrounded by a puffy orange disk of gas and dust. Above and below the center of the disk are blue cones representing the corona. At the start of the sequence, a flash of purple-white light travels from the edges of the disk inward, until the whole thing is illuminated. That light fades and then there is a flare of blue light above and below the center. This image is watermarked “Artist’s concept.” Credit: NASA’s Goddard Space Flight Center

Active galaxies

Usually, we think of galaxies – and most other things in the universe – as changing so slowly that we can’t see the changes. But about 10% of the universe’s galaxies are active, which means their black hole-powered centers are very bright and have a lot going on. They can produce high-speed particle jets or flares of light. Sometimes scientists can catch and watch these real-time changes.

For example, for several years starting in 2018, Swift and other telescopes observed changes in a galaxy’s X-ray and ultraviolet light that led them to think the galaxy’s magnetic field had flipped 180 degrees.

This animation depicts a giant flare on the surface of a magnetar. The object’s glowing surface, covered in swirls of lighter and darker blue, fills the lower right corner of the image. The powerful magnetic field surrounding this stellar corpse is represented by thin white speckled loops that arc off the surface and continue past the edges of the image. A starquake rocks the surface of the magnetar, abruptly affecting its magnetic field and producing a quick, powerful pulse of X-rays and gamma rays, represented by a magenta glow. The event also ejects electrons and positrons traveling at about 99% the speed of light. These are represented by a blue blob, which follows the gamma rays heading towards the upper left and off-screen. The image is watermarked “Artist’s concept.” Credit: NASA’s Goddard Space Flight Center/Chris Smith (USRA/GESTAR)

Magnetic star remnants

Magnetars are a type of neutron star, a very dense leftover of a massive star that exploded in a supernova. Magnetars have the strongest magnetic fields we know of — up to 10 trillion times more intense than a refrigerator magnet and a thousand times stronger than a typical neutron star’s.

Occasionally, magnetars experience outbursts related to sudden changes in their magnetic fields that can last for months or even years. Swift detected such an outburst from a magnetar in 2020. The satellite’s X-ray observations helped scientists determine that the city-sized object was rotating once every 10.4 seconds.

This gif shows six snapshots of comet 2I/Borisov as it traveled through our solar system. They were captured with the Ultraviolet/Optical Telescope aboard NASA’s Neil Gehrels Swift Observatory. The first four images are a dark purple color with streaks of white traveling across them. Borisov is a faint white smudge in the center. The fifth image has a blue background with the same white streaks. The last image is just the blue background. The image is watermarked with “Ultraviolet” on the left side. On the right are rotating labels showing the date of each snapshot: Sept 27, Nov 1, Dec 1, Dec 21, Jan 14, Feb 17. Credit: NASA/Swift/Z. Xing et al. 2020

Comets

Swift has also studied comets in our own solar system. Comets are town-sized snowballs of frozen gases, rock, and dust. When one gets close to our Sun, it heats up and spews dust and gases into a giant glowing halo.

In 2019, Swift watched a comet called 2I/Borisov. Using ultraviolet light, scientists calculated that Borisov lost enough water to fill 92 Olympic-size swimming pools! (Another interesting fact about Borisov: Astronomers think it came from outside our solar system.)

This animation shows a spacecraft, NASA’s Neil Gehrels Swift Observatory, in orbit above Earth. Swift is composed of a long cylinder at the center, wrapped in golden foil. At the front of the cylinder is a silver sunshade protruding over several telescopes. Two black solar arrays are attached on either side of the cylinder, extending like wings. The animation begins with a view of Swift with Earth in the background. Then the camera pans along one side of the spacecraft until Swift is seen looking out into space. Credit: NASA's Goddard Space Flight Center Conceptual Image Lab

What's next for Swift?

Swift has studied a lot of cool events and objects over its two decades, but there are still a few events scientists are hoping it’ll see.

Swift is an important part of a new era of astrophysics called multimessenger astronomy, which is where scientists use light, particles, and space-time ripples called gravitational waves to study different aspects of cosmic events.

A cartoon of different cosmic messengers. On top are particles, which show as four different colored dots that have trails appearing behind them, evoking movement. In the middle is light, which is shown as a wave moving through space. On the bottom are gravitational waves. These are shown as a series of ovals that expand and contract in sequence to evoke the feeling of an elastic tube that is growing and shrinking in width. The image is watermarked “Artist’s concept.” Credit: NASA’s Goddard Space Flight Center

In 2017, Swift and other observatories detected light and gravitational waves from the same event, a gamma-ray burst, for the first time. But what astronomers really want is to detect all three messengers from the same event.

As Swift enters its 20th year, it’ll keep watching the ever-changing sky.

Keep up with Swift through NASA Universe on X, Facebook, and Instagram. And make sure to follow us on Tumblr for your regular dose of space!

2K notes View Post

taylorswift-iraqifan

2 months ago

so you’re really telling me that grown man can rip out, smash up, and carry around traffic light poles post-super bowl win and that’s totally acceptable behaviour, but as soon as girls and women alike cry at a concert because they are seeing their favourite artist live, those same men get online and start mocking them by saying they are being too emotional and dramatic… right okay

928 notes View Post

taylorswift-iraqifan

7 months ago