Hubble Spots Two Interacting Galaxies Defying Cosmic Convention

The Past, Present and Future of Exploration on Mars

Today, we’re celebrating the Red Planet! Since our first close-up picture of Mars in 1965, spacecraft voyages to the Red Planet have revealed a world strangely familiar, yet different enough to challenge our perceptions of what makes a planet work.

You’d think Mars would be easier to understand. Like Earth, Mars has polar ice caps and clouds in its atmosphere, seasonal weather patterns, volcanoes, canyons and other recognizable features. However, conditions on Mars vary wildly from what we know on our own planet.

Join us as we highlight some of the exploration on Mars from the past, present and future:

PAST

Viking Landers

Our Viking Project found a place in history when it became the first U.S. mission to land a spacecraft safely on the surface of Mars and return images of the surface. Two identical spacecraft, each consisting of a lander and an orbiter, were built. Each orbiter-lander pair flew together and entered Mars orbit; the landers then separated and descended to the planet’s surface.

Besides taking photographs and collecting other science data, the two landers conducted three biology experiments designed to look for possible signs of life.

Pathfinder Rover

In 1997, Pathfinder was the first-ever robotic rover to land on the surface of Mars. It was designed as a technology demonstration of a new way to deliver an instrumented lander to the surface of a planet. Mars Pathfinder used an innovative method of directly entering the Martian atmosphere, assisted by a parachute to slow its descent and a giant system of airbags to cushion the impact.

Pathfinder not only accomplished its goal but also returned an unprecedented amount of data and outlived its primary design life.

PRESENT

Spirit and Opportunity

In January 2004, two robotic geologists named Spirit and Opportunity landed on opposite sides of the Red Planet. With far greater mobility than the 1997 Mars Pathfinder rover, these robotic explorers have trekked for miles across the Martian surface, conducting field geology and making atmospheric observations. Carrying identical, sophisticated sets of science instruments, both rovers have found evidence of ancient Martian environments where intermittently wet and habitable conditions existed.

Both missions exceeded their planned 90-day mission lifetimes by many years. Spirit lasted 20 times longer than its original design until its final communication to Earth on March 22, 2010. Opportunity continues to operate more than a decade after launch.

Mars Reconnaissance Orbiter

Our Mars Reconnaissance Orbiter left Earth in 2005 on a search for evidence that water persisted on the surface of Mars for a long period of time. While other Mars missions have shown that water flowed across the surface in Mars’ history, it remained a mystery whether water was ever around long enough to provide a habitat for life.

In addition to using the rover to study Mars, we’re using data and imagery from this mission to survey possible future human landing sites on the Red Planet.

Curiosity

The Curiosity rover is the largest and most capable rover ever sent to Mars. It launched November 26, 2011 and landed on Mars on Aug. 5, 2012. Curiosity set out to answer the question: Did Mars ever have the right environmental conditions to support small life forms called microbes? 

Early in its mission, Curiosity’s scientific tools found chemical and mineral evidence of past habitable environments on Mars. It continues to explore the rock record from a time when Mars could have been home to microbial life.

FUTURE

Space Launch System Rocket

We’re currently building the world’s most powerful rocket, the Space Launch System (SLS). When completed, this rocket will enable astronauts to begin their journey to explore destinations far into the solar system, including Mars.

Orion Spacecraft

The Orion spacecraft will sit atop the Space Launch System rocket as it launches humans deeper into space than ever before. Orion will serve as the exploration vehicle that will carry the crew to space, provide emergency abort capability, sustain the crew during the space travel and provide safe re-entry from deep space return velocities.

Mars 2020

The Mars 2020 rover mission takes the next step in exploration of the Red Planet by not only seeking signs of habitable conditions in the ancient past, but also searching for signs of past microbial life itself.

The Mars 2020 rover introduces a drill that can collect core samples of the most promising rocks and soils and set them aside in a “cache” on the surface of Mars. The mission will also test a method for producing oxygen from the Martian atmosphere, identify other resources (such as subsurface water), improve landing techniques and characterize weather, dust and other potential environmental conditions that could affect future astronauts living and working on the Red Planet.

For decades, we’ve sent orbiters, landers and rovers, dramatically increasing our knowledge about the Red Planet and paving the way for future human explorers. Mars is the next tangible frontier for human exploration, and it’s an achievable goal. There are challenges to pioneering Mars, but we know they are solvable. 

To discover more about Mars exploration, visit: https://www.nasa.gov/topics/journeytomars/index.html

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

Soyuz MS-10 experiences launch anomaly; crew aborts to safe landing.

One of Russia’s most reliable launchers experienced a rare, in-flight anomaly earlier this morning, forcing the two-man crew of Soyuz MS-10 to abort the mission.

Following a normal liftoff at 4:40am EST (2:40pm local time), a malfunction in the Soyuz FG rocket two minutes into the flight forced Expedition 57 crewmembers Alexey Ovchinin and Nick Hague to abort a manual abort profile. The anomaly occurred immediately following the separation of the rocket’s four strap-on boosters and jettisoning of the Launch Escape System. However, the protective fairing covering the spacecraft during flight through the thick atmosphere was still on, and solid rocket motors attached to the fairing pulled the crew capsule away from the failing booster. Following a ballistic trajectory through the upper atmosphere, the Soyuz’s Descent module separated from the Orbital Module and payload fairing and descended to a safe landing 20 kilometers east of Zezkezhan, Kazakhstan, 34 minutes after launch. Roscosmos reported that the crewmembers experienced around seven times the force of gravity, or 7G’s, during their abort. 

Recovery forces reached the landing site immediately following touchdown. Both astronauts were reported to be in good health following their ordeal, and returned to their families at the Baikonur launch site around six hours after liftoff.

Recovery forces at the Soyuz MS-10 emergency landing site. Source: Ruptly.

Soyuz MS-10 crewmembers Alexey Ovchinin and Nick Hague embrace their families following their return to the Baikonur Cosmodrome after today’s launch mishap. Credit: NASA/Bill Ingalls. This marks the first crewed launch mishap of the International Space Station program, the first crewed launch mishap since the Challenger disaster in 1986, and the first crewed Soyuz launch malfunction since Soyuz T-10 in 1983.

That incident saw the two-man crew of Vladimir Titov and Gennady Strekalov abort away from their exploding rocket shortly before its scheduled liftoff time.  While no cause of the mishap is currently known, Russian authorities have begun an investigation of the incident and have temporarily grounded all future Soyuz flights.  The current three-member crew of Expedition 57 is slated to return to Earth December 13, followed by the launch of Expedition 58 December 20. Following today’s anomaly, it is unclear whether Expedition 57 will remain on orbit longer, or when the next crew will launch to the station. Expedition 57 is able to remain on orbit until early January, when their Soyuz reaches its certified orbital lifetime.

Expedition 57 commander Alexander Gerst captured this image of the Soyuz MS-10 launch from the International Space Station. The anomalous nature of the launch is evidenced by multiple points of light along the ascent path. Source: NASA. Watch NASA TV coverage of the Soyuz MS-10 launch below.

P/c: NASA.

Ep. 20 Challenger - HD and the Void

January 28th was the anniversary of the Challenger space shuttle disaster, and while I do discuss what happened, I talk more about the American space shuttle program and what the repercussions of this disaster were for NASA as an agency. I have cl...

I had to skip last week to finish an article on STEM but it got me a really awesome intro to a very serious episode. Learn this week about 1) Sally Ride (a bit, just like the highlight reel on her) 2) NASA’s space shuttle program 3) the Challenger disaster that occurred January 28, 1986. It was the anniversary of this tragedy yesterday and I wanted to learn more about it and why it happened and what, ultimately, came out of that difficult time in the space shuttle program. 

I have a quick and easy way for you to cut out listening to the actual recap of the disaster if you don’t want to hear about it and just want to hear the fun space shuttle facts and the changes that NASA undertook in learning from Challenger’s destruction. Below the cut are my sources, music credits, a vocab list, and the transcript of this episode. I’ve bolded those sources I mention in the podcast, and I do have a trigger warning for the actual, live-coverage footage of the Challenger disaster. Please let me know what you think I should research next by messaging me here, tweeting at me at @HDandtheVoid, or asking me to my face if you know me. I’d love it if you would subscribe on iTunes (especially since I seem to have so many problems this month with consistent timing), rate my humble little podcast and maybe review it, and tell friends if you think they’d like to hear it!

(My thoughts on the next episode are national radio quiet zones, or I could go into the transit of Venus. The next episode will go up February 12th.)

Glossary

gimbaled - moveable. In a gimbaled thrust system for rockets, the exhaust  nozzel of the rocket can be swiveled from side to side, which changes the direction of that thrust relative to rocket’s center of gravity.

pitch - in flight, this is rotation around the side-to-side axis. If the object’s nose points upwards or downwards, this is changing its pitch.

roll - in flight, this is rotation around the front-to-back axis. If the object’s wings spin from horizontal to vertical, it’s rolling.

yaw - in flight, this is rotation around the vertical axis. If the pilot turns the object so they can see more to the left or to the right, with no change in the horizon’s position, this is changing its yaw.

Script/Transcript

Sources

Sally Ride (for K-4) via NASA

Sally Ride bio via NASA

Sally Ride via the Smithsonian National Air and Space Museum

Sally Ride and her sexuality via Slates blog ‘Outward’ (May 2014)

Sexual Orientation Discrimination Policy via NASA

“Employees should expect to find a diversity of sexual orientations at NASA. In the past, it was common practice to fire or to refuse to hire suspected homosexuals in the Federal workplace. Employees have been physically threatened, verbally abused, and subjected to hostile working conditions. Laws and policies have changed, and all NASA employees need to be aware of their responsibility to prevent this form of discrimination and to ensure that lesbian, gay, bisexual, and transgender (LGBT) individuals are an accepted and valued part of the diverse NASA workforce.”

Space shuttle era via NASA

1983-1986: The Missions and History of Space Shuttle Challenger via NASA Spaceflight

Space shuttle process via NASA (archived)

Space shuttle components via NASA

Gimbaled thrust via NASA

Roll, Pitch, and Yaw via the Smithsonian National Air and Space Museum

Typical shuttle mission via NASA

Challenger via Space.com (Nov 2017)

Challenger disaster via History.com — contains an autoplay video

Challenger disaster live on CNN via YouTube (Jan 2011)—tw: destruction occurs at timecode 1:35

Challenger myths debunked via National Geographic (Jan 2016)

Intro Music: ‘Better Times Will Come’ by No Luck Club off their album Prosperity

Filler Music: ‘Repent’ by Dreamend off their album And So I Ate Myself, Bite By Bite, which has cover art that scared the hell out of me when my friend gave it to me because I was on painkillers for a shattered radial head. Really good band, though.

Outro Music: ‘Fields of Russia’ by Mutefish off their album On Draught

30 Doradus, located in the heart of the Tarantula nebula, is the brightest star-forming region in our galactic neighborhood. The nebula resides 170,000 light-years away in the Large Magellanic Cloud. Links to very large images in comments.

js

My microphone just arrived! Now to set it up and figure out how the hell it works....

What's Made in a Thunderstorm and Faster Than Lightning? Gamma Rays!

A flash of lightning. A roll of thunder. These are normal stormy sights and sounds. But sometimes, up above the clouds, stranger things happen. Our Fermi Gamma-ray Space Telescope has spotted bursts of gamma rays - some of the highest-energy forms of light in the universe - coming from thunderstorms. Gamma rays are usually found coming from objects with crazy extreme physics like neutron stars and black holes. 

So why is Fermi seeing them come from thunderstorms?

Thunderstorms form when warm, damp air near the ground starts to rise and encounters colder air. As the warm air rises, moisture condenses into water droplets. The upward-moving water droplets bump into downward-moving ice crystals, stripping off electrons and creating a static charge in the cloud.

The top of the storm becomes positively charged, and the bottom becomes negatively charged, like two ends of a battery. Eventually the opposite charges build enough to overcome the insulating properties of the surrounding air - and zap! You get lightning.

Scientists suspect that lightning reconfigures the cloud’s electrical field. In some cases this allows electrons to rush toward the upper part of the storm at nearly the speed of light. That makes thunderstorms the most powerful natural particle accelerators on Earth!

When those electrons run into air molecules, they emit a terrestrial gamma-ray flash, which means that thunderstorms are creating some of the highest energy forms of light in the universe. But that’s not all - thunderstorms can also produce antimatter! Yep, you read that correctly! Sometimes, a gamma ray will run into an atom and produce an electron and a positron, which is an electron’s antimatter opposite!

The Fermi Gamma-ray Space Telescope can spot terrestrial gamma-ray flashes within 500 miles of the location directly below the spacecraft. It does this using an instrument called the Gamma-ray Burst Monitor which is primarily used to watch for spectacular flashes of gamma rays coming from the universe.

There are an estimated 1,800 thunderstorms occurring on Earth at any given moment. Over the 10 years that Fermi has been in space, it has spotted about 5,000 terrestrial gamma-ray flashes. But scientists estimate that there are 1,000 of these flashes every day - we’re just seeing the ones that are within 500 miles of Fermi’s regular orbits, which don’t cover the U.S. or Europe.

The map above shows all the flashes Fermi has seen since 2008. (Notice there’s a blob missing over the lower part of South America. That’s the South Atlantic Anomaly, a portion of the sky where radiation affects spacecraft and causes data glitches.)

Fermi has also spotted terrestrial gamma-ray flashes coming from individual tropical weather systems. The most productive system we’ve seen was Tropical Storm Julio in 2014, which later became a hurricane. It produced four flashes in just 100 minutes!

Learn more about what Fermi’s discovered about gamma rays over the last 10 years and how we’re celebrating its accomplishments.

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

Just a reminder that the first NASA astronauts were supposed to be women because generally they are smaller, lighter (less weight in the cockpit means less fuel required) and eat less than men and so would be easier to accommodate in space. 

Solar System by Jian Guo

One-year countdown to solar eclipse, August 21, 2017: path of totality overlaid on U.S. population density and interstate map.

     Meet SA-500D, the first Saturn V rocket. Wernher von Braun designed her as the dynamic test article for the program. She was assembled stage by stage inside the Dynamic Test Stand at NASA Marshall Spaceflight Center, then subjected to lateral, longitudinal, and torsional vibrations equal of that of launch for a total of 450 hours.

     The first time I visited SA-500D in 1999, she was outside on the US Space and Rocket Center property. Her paint was faded and worn, having sat there since 1969. In 2005, full restoration began, and she was moved inside her new facility, the Davidson Center for Space Exploration in Huntsville, Alabama. I’m happy to report that as of Sunday, April 27, 2014, she looks great. Viewing the newly restored rocket is magnitudes more impactful. The difference is incredible.