Solar System: Things To Know This Week

Black Holes: Seeing the Invisible!

Black holes are some of the most bizarre and fascinating objects in the cosmos. Astronomers want to study lots of them, but there’s one big problem – black holes are invisible! Since they don’t emit any light, it’s pretty tough to find them lurking in the inky void of space. Fortunately there are a few different ways we can “see” black holes indirectly by watching how they affect their surroundings.

Speedy stars

If you’ve spent some time stargazing, you know what a calm, peaceful place our universe can be. But did you know that a monster is hiding right in the heart of our Milky Way galaxy? Astronomers noticed stars zipping superfast around something we can’t see at the center of the galaxy, about 10 million miles per hour! The stars must be circling a supermassive black hole. No other object would have strong enough gravity to keep them from flying off into space.

Two astrophysicists won half of the Nobel Prize in Physics last year for revealing this dark secret. The black hole is truly monstrous, weighing about four million times as much as our Sun! And it seems our home galaxy is no exception – our Hubble Space Telescope has revealed that the hubs of most galaxies contain supermassive black holes.

Shadowy silhouettes

Technology has advanced enough that we’ve been able to spot one of these supermassive black holes in a nearby galaxy. In 2019, astronomers took the first-ever picture of a black hole in a galaxy called M87, which is about 55 million light-years away. They used an international network of radio telescopes called the Event Horizon Telescope.

In the image, we can see some light from hot gas surrounding a dark shape. While we still can’t see the black hole itself, we can see the “shadow” it casts on the bright backdrop.

Shattered stars

Black holes can come in a smaller variety, too. When a massive star runs out of the fuel it uses to shine, it collapses in on itself. These lightweight or “stellar-mass” black holes are only about 5-20 times as massive as the Sun. They’re scattered throughout the galaxy in the same places where we find stars, since that’s how they began their lives. Some of them started out with a companion star, and so far that’s been our best clue to find them.

Some black holes steal material from their companion star. As the material falls onto the black hole, it gets superhot and lights up in X-rays. The first confirmed black hole astronomers discovered, called Cygnus X-1, was found this way.

If a star comes too close to a supermassive black hole, the effect is even more dramatic! Instead of just siphoning material from the star like a smaller black hole would do, a supermassive black hole will completely tear the star apart into a stream of gas. This is called a tidal disruption event.

Making waves

But what if two companion stars both turn into black holes? They may eventually collide with each other to form a larger black hole, sending ripples through space-time – the fabric of the cosmos!

These ripples, called gravitational waves, travel across space at the speed of light. The waves that reach us are extremely weak because space-time is really stiff.

Three scientists received the 2017 Nobel Prize in Physics for using LIGO to observe gravitational waves that were sent out from colliding stellar-mass black holes. Though gravitational waves are hard to detect, they offer a way to find black holes without having to see any light.

We’re teaming up with the European Space Agency for a mission called LISA, which stands for Laser Interferometer Space Antenna. When it launches in the 2030s, it will detect gravitational waves from merging supermassive black holes – a likely sign of colliding galaxies!

Rogue black holes

So we have a few ways to find black holes by seeing stuff that’s close to them. But astronomers think there could be 100 million black holes roaming the galaxy solo. Fortunately, our Nancy Grace Roman Space Telescope will provide a way to “see” these isolated black holes, too.

Roman will find solitary black holes when they pass in front of more distant stars from our vantage point. The black hole’s gravity will warp the starlight in ways that reveal its presence. In some cases we can figure out a black hole’s mass and distance this way, and even estimate how fast it’s moving through the galaxy.

For more about black holes, check out these Tumblr posts!

⚫ Gobble Up These Black (Hole) Friday Deals!

⚫ Hubble’s 5 Weirdest Black Hole Discoveries

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Next stop: Mars! Watch NASA's Perseverance Rover Attempt the Most Dangerous Landing to Date on Feb. 18

Tomorrow, Feb. 18, 2021, our most advanced rover named Perseverance will attempt a precision landing in Mars' Jezero Crater. Her mission is to search for signs of ancient life in the planet's geology and test technology that will pave the way for future human missions to the Moon and Mars. Excited yet? Get this:

Perseverance is ferrying 25 cameras to the Red Planet — the most ever flown in the history of deep-space exploration — so get ready to see Mars like never before! For more mission quick facts, click here.

When to watch:

Date: Feb. 18

Time: Live coverage starts at 2:15 p.m. EST (19:15 UTC)

SET A REMINDER & WATCH LIVE HERE

Want to join the #CountdownToMars? We created a virtual Mars photo booth, have sounds of Mars to listen to and more for all you Earthlings to channel your inner Martian. Check out ways to participate HERE.

If you want to follow Perseverance's journey on the Red Planet, be sure to follow her on Facebook and Twitter.

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Welcome to the new, official NASA Tumblr. We’re going to be giving you a regular dose of space here. Follow along and join us as we share information, images and video about our mission of exploration and discovery. First up, check out the moon photobombing Earth in this new animated gif. The far side of the moon, illuminated by the sun, is seen as it crosses between our 'EPIC' camera on the Deep Space Climate Observatory (DSCOVR) satellite, and the Earth - one million miles away. Check it out: http://go.nasa.gov/1Dq0IO9

Cascading loops on the surface of the sun highlight an active region that had just rotated into view of our solar-observing spacecraft. We have observed this phenomenon numerous times, but this one was one of the longest and clearest sequences we have seen in years. 

The bright loops are actually charged particles spinning along the magnetic field lines! The action was captured in a combination of two wavelengths of extreme ultraviolet light over a period of about 20 hours. 

Take a closer look: https://sdo.gsfc.nasa.gov/gallery/potw/item/798

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❤️🧡💛 Color the Cosmos 💚💙💜

📣 Attention, space explorers! Our Nancy Grace Roman Space Telescope presents: two new coloring pages! Unleash your creativity to bring these celestial scenes to life.

Nancy Grace Roman, NASA’s first chief astronomer, smiles out at us from our first coloring page. She’s considered the mother of our Hubble Space Telescope because she helped everyone understand why it was important to have observatories in space – not just on the ground. If it weren’t for her, Hubble may have never become a reality.

The Roman Space Telescope is named after her to honor the legacy she left behind when she died in 2018. Thanks to Nancy Grace Roman, we’ve taken countless pictures of space from orbiting telescopes and learned so much more about the universe than we could have possibly known otherwise!

The second coloring page illustrates some of the exciting science topics the Roman Space Telescope will explore. Set to launch in the mid-2020s, the mission will view the universe in infrared light, which is like using heat vision. We’ll be able to peer through clouds of dust and see things that are much farther away.

We anticipate all kinds of discoveries from the edge of our solar system to the farthest reaches of space. This coloring page highlights a few of the things the Roman Space Telescope will help us learn more about. The mission will find thousands of planets beyond our solar system and hundreds of millions of galaxies. It will also help us unravel the mysteries of dark matter and dark energy, represented by the gray web-like pattern in the background. With so much exciting new data, who knows what else we may learn?

Download the coloring pages here!

Learn more about the Roman Space Telescope at: https://roman.gsfc.nasa.gov/

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

GPS: Coming to a Moon Near You!

The next generation of lunar explorers – the Artemis generation – will establish a sustained presence on the Moon, making revolutionary discoveries, prospecting for resources and proving technologies key to future deep space exploration. To support these ambitions, our navigation engineers are developing an architecture that will provide accurate, robust location services all the way out to lunar orbit.

How? We’re teaming up with the U.S. Air Force to extend the use of GPS in space by developing advanced space receivers capable of tracking weak GPS signals far out in space.

Spacecraft near Earth have long relied on GPS signals for navigation data, just as users on the ground might use their phones to maneuver through a highway system. Below approximately 1,860 miles, spacecraft in low-Earth orbit can rely on GPS for near-instantaneous location data. This is an enormous benefit to these missions, allowing many satellites the autonomy to react and respond to unforeseen events without much hands-on oversight.

Beyond this altitude, navigation becomes more challenging. To reliably calculate their position, spacecraft must use signals from the global navigation satellite system (GNSS), the collection of international GPS-like satellite constellations. The region of space that can be serviced by these satellites is called the Space Service Volume, which extends from 1,860 miles to about 22,000 miles, or geosynchronous orbit.

In this area of service, missions don’t rely on GNSS signals in the same way one would on Earth or in low-Earth orbit. They orbit too high to “see” enough signals from GNSS satellites on their side of the globe, so they must rely on signals from GNSS satellite signals spilling over to the opposite side of the globe.  This is because the Earth blocks the main signals of these satellites, so the spacecraft must “listen” for the fainter signals that extend out from the sides of their antennas, known as “side-lobes.”

Though 22,000 miles is considered the end of the Space Service Volume, that hasn’t stopped our engineers from reaching higher. In fact, our simulations prove that GNSS signals could even be used for reliable navigation in lunar orbit, far outside the Space Service Volume, over 200,000 miles from Earth. We’re even planning to use GNSS signals in the navigation architecture for the Gateway, an outpost in orbit around the Moon that will enable sustained lunar surface exploration.

It’s amazing that the same systems you might use to navigate the highways are putting us on the path forward to the Moon!

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

Follow NASA’s Artemis I Moon Mission: Live Tracker, Latest Images, and Videos

On Nov. 16, 2022, the Artemis I mission officially began with the launch of the Orion spacecraft atop the Space Launch System rocket. The rocket and spacecraft lifted off from historic Launch Complex 39B at NASA’s Kennedy Space Center in Florida.

Now, the Orion spacecraft is about halfway through its journey around the Moon. Although the spacecraft is uncrewed, the Artemis I mission prepares us for future missions with astronauts, starting with Artemis II.

Stay up-to-date with the mission with the latest full-resolution images, mission updates, on-demand and live video.

Imagery:

Find full-resolution images from the Orion spacecraft as they are released here.

Launch imagery can be found here. When Orion splashes down in the Pacific Ocean on Dec. 11, the images will be available here, as well!

Videos:

This playlist contains informational videos, as well as upcoming and past live events, about Artemis I.

You can watch a livestream of the Artemis I mission here. (Just a note: the livestream may cut off during moments when the Orion team needs higher bandwidth for activities.)

Keep yourself updated on the upcoming broadcasts of Artemis milestones with the NASA TV schedule.

Trackers:

Our Artemis I Tracker uses live telemetry data streamed directly from Mission Control Center in Houston to show Orion position, attitude, solar array positions, and thruster firings throughout the mission.

“Eyes on the Solar System” shows Orion's position along the Artemis I trajectory and in relation to other NASA spacecraft and objects in the solar system.

“DSN Now” shows which antenna on Earth’s Deep Space Network is communicating with Orion.

Updates:

Read up on where Orion is and what’s next in the Artemis I mission with the Mission Blog.

Thank you so much for following with us on this historic mission. Go Artemis!

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

Has the COVID-19 pandemic really reduced pollution in areas participating in lockdowns? Is the environment “recovering”?

10 Things: Why Cassini Mattered

One year ago, on Sept. 15, 2017, NASA’s Cassini spacecraft ended its epic exploration of Saturn with a planned dive into the planet’s atmosphere--sending back new science to the last second. The spacecraft is gone, but the science continues. Here are 10 reasons why Cassini mattered...

1. Game Changers

Cassini and ESA (European Space Agency)’s Huygens probe expanded our understanding of the kinds of worlds where life might exist.

2. A (Little) Like Home

At Saturn’s largest moon, Titan, Cassini and Huygens showed us one of the most Earth-like worlds we’ve ever encountered, with weather, climate and geology that provide new ways to understand our home planet.

3. A Time Machine (In a Sense)

Cassini gave us a portal to see the physical processes that likely shaped the development of our solar system, as well as planetary systems around other stars.

4. The Long Run

The length of Cassini’s mission enabled us to observe weather and seasonal changes over nearly half of a Saturn year, improving our understanding of similar processes at Earth, and potentially those at planets around other stars.

5. Big Science in Small Places

Cassini revealed Saturn’s moons to be unique worlds with their own stories to tell.

6. Ringscape

Cassini showed us the complexity of Saturn’s rings and the dramatic processes operating within them.

7. Pure Exploration

Some of Cassini’s best discoveries were serendipitous. What Cassini found at Saturn prompted scientists to rethink their understanding of the solar system.

8. The Right Tools for the Job

Cassini represented a staggering achievement of human and technical complexity, finding innovative ways to use the spacecraft and its instruments, and paving the way for future missions to explore our solar system.

9. Jewel of the Solar System

Cassini revealed the beauty of Saturn, its rings and moons, inspiring our sense of wonder and enriching our sense of place in the cosmos.

10. Much Still to Teach Us

The data returned by Cassini during its 13 years at Saturn will continue to be studied for decades, and many new discoveries are undoubtedly waiting to be revealed. To keep pace with what’s to come, we’ve created a new home for the mission--and its spectacular images--at https://solarsystem.nasa.gov/cassini.

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

GOES-R: The Future of Forecasting

What is GOES-R?

The Geostationary Operational Environmental Satellite-R Series (GOES-R) is the nation’s next generation of geostationary weather satellites. It is the first of four satellites to be launched for the National Oceanic and Atmospheric Administration (NOAA).

The GOES-R satellite will provide advanced imaging with increased spatial resolution and faster coverage for more accurate forecasts, real-time mapping of lightning activity and improved monitoring of solar activity. For the first time, GOES-R will be able to monitor the Earth in near real-time.

Once in geostationary orbit (the orbit around the Earth’s equator), it will provide images of weather patterns and severe storms across the continental U.S. as regularly as every five minutes. Images of smaller, more detailed areas, where storm activity is present, will be taken as frequently as every 30 seconds.

These images can be used to aid in formulating regular forecasts, term forecasting, such as seasonal predictions and drought outlooks.

In addition, the satellite will constantly monitor space weather conditions, such as solar flares, to provide advance notice of potential communication and navigation disruptions.

The satellite will also assist researchers in understanding the interactions between land, oceans, the atmosphere and climate.

What will GOES-R Do?

Improve hurricane tracking and intensity forecasts

Increase thunderstorm and tornado warning lead time

Give earlier warning of ground lightning strike hazards

Improve detection of heavy rainfall and flash flooding risks

Improve air quality warnings and alerts

Give better fire detection and intensity estimation

Improve solar flare warnings for communications and navigation disruptions

Give more accurate monitoring of energetic particles responsible for radiation hazards to humans and spacecraft

Improve monitoring of space weather to get better geomagnetic storm forecasting.

The better we can predict what’s coming, the better we can prepare.

Launch Activities!

The GOES-R satellite is targeted for a launch on Saturday, Nov. 19, aboard a United Launch Alliance Atlas V rocket. 

The one-hour launch window opens at 5:42 p.m. EST. Liftoff will occur from our Kennedy Space Center in Florida.

Join us leading up to launch by tuning in during the following times:

Thursday, Nov. 17 Prelaunch News Conference - 1 p.m. EST Watch HERE

GOES-R Mission Briefing - 2 p.m. EST Watch HERE

Friday, Nov. 18 GOES-R Social Presentations – 1:30 p.m. EST Watch HERE

Saturday, Nov. 19 NASA Edge Prelaunch Program – 3:45 p.m. EST Watch HERE

Launch Coverage & Commentary – 4:45 p.m. EST Watch HERE

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