Great Detail Of The Famous Crawler That Transported The Mighty Saturn V And All The Space Shuttles To

I mention New Horizons in today’s podcast but here’s some more up-to-date info!

Solar System: Things to Know This Week

Time for a little reconnaissance. 

Our New Horizons spacecraft won’t arrive at its next destination in the distant Kuiper Belt—an object known as 2014 MU69—until New Year’s Day 2019, but researchers are already starting to study its environment thanks to a few rare observational opportunities this summer, including one on July 17. This week, we’re sharing 10 things to know about this exciting mission to a vast region of ancient mini-worlds billions of miles away.

1. First, Some Background 

New Horizons launched on Jan. 19, 2006. It swung past Jupiter for a gravity boost and scientific studies in February 2007, and conducted a six-month reconnaissance flyby study of Pluto and its moons in summer 2015. The mission culminated with the closest approach to Pluto on July 14, 2015. Now, as part of an extended mission, the New Horizons spacecraft is heading farther into the Kuiper Belt.

2. A Kuiper Belt refresher

The Kuiper Belt is a region full of objects presumed to be remnants from the formation of our solar system some 4.6 billion years ago. It includes dwarf planets such as Pluto and is populated with hundreds of thousands of icy bodies larger than 62 miles (100 km) across and an estimated trillion or more comets. The first Kuiper Belt object was discovered in 1992.

3. That’s Pretty Far

When New Horizons flies by MU69 in 2019, it will be the most distant object ever explored by a spacecraft. This ancient Kuiper Belt object is not well understood because it is faint, small, and very far away, located approximately 4.1 billion miles (6.6 billion km) from Earth.

4. Shadow Play 

To study this distant object from Earth, the New Horizons team have used data from the Hubble Space Telescope and the European Space Agency’s Gaia satellite to calculate where MU69 would cast a shadow on Earth’s surface as it passes in front of a star, an event known as an occultation.

5. An International Effort 

One occultation occurred on June 3, 2017. More than 50 mission team members and collaborators set up telescopes across South Africa and Argentina, aiming to catch a two-second glimpse of the object’s shadow as it raced across the Earth. Joining in on the occultation observations were NASA’s Hubble Space Telescope and Gaia, a space observatory of the European Space Agency (ESA).

6. Piecing Together the Puzzle 

Combined, the pre-positioned mobile telescopes captured more than 100,000 images of the occultation star that can be used to assess the Kuiper Belt object’s environment. While MU69 itself eluded direct detection, the June 3 data provided valuable and surprising insights. “These data show that MU69 might not be as dark or as large as some expected,” said occultation team leader Marc Buie, a New Horizons science team member from Southwest Research Institute in Boulder, Colorado.

7. One Major Missing Piece 

Clear detection of MU69 remains elusive. “These [June 3 occultation] results are telling us something really interesting,” said New Horizons Principal Investigator Alan Stern, of the Southwest Research Institute. “The fact that we accomplished the occultation observations from every planned observing site but didn’t detect the object itself likely means that either MU69 is highly reflective and smaller than some expected, or it may be a binary or even a swarm of smaller bodies left from the time when the planets in our solar system formed.”

8. Another Opportunity 

On July 10, the SOFIA team positioned its aircraft in the center of the shadow, pointing its powerful 100-inch (2.5-meter) telescope at MU69 when the object passed in front of the background star. The mission team will now analyze that data over the next few weeks, looking in particular for rings or debris around MU69 that might present problems for New Horizons when the spacecraft flies by in 2019. “This was the most challenging occultation observation because MU69 is so small and so distant,” said Kimberly Ennico Smith, SOFIA project scientist.

9. The Latest 

On July 17, the Hubble Space Telescope will check for debris around MU69 while team members set up another “fence line” of small mobile telescopes along the predicted ground track of the occultation shadow in southern Argentina.

10. Past to Present 

New Horizons has had quite the journey. Check out some of these mission videos for a quick tour of its major accomplishments and what’s next for this impressive spacecraft.

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10 Things: Mysterious 'Oumuamua

The interstellar object ‘Oumuamua perplexed scientists in October 2017 as it whipped past Earth at an unusually high speed. This mysterious visitor is the first object ever seen in our solar system that is known to have originated elsewhere.  Here are five things we know and five things we don’t know about the first confirmed interstellar object to pass through our solar system.

1. We know it’s not from around here.

 The object known as 1I/2017 U1 (and nicknamed ‘Oumuamua) was traveling too fast (196,000 mph, that’s 54 miles per second or 87.3 kilometers per second) to have originated in our solar system. Comets and asteroids from within our solar system move at a slower speed, typically an average of 12 miles per second (19 kilometers per second) . In non-technical terms, 'Oumuamua is an “interstellar vagabond.”

Artist impression of the interstellar object ‘Oumuamua. Credit: ESA/Hubble, NASA, ESO, M. Kornmesser

2. We’re not sure where it came from.

'Oumuamua entered our solar system from the rough direction of the constellation Lyra, but it’s impossible to tell where it originally came from. Thousands of years ago, when 'Oumuamua started to wander from its parent planetary system, the stars were in a different position so it’s impossible to pinpoint its point of origin. It could have been wandering the galaxy for billions of years.

3. We know it’s out of here.

'Oumuamua is headed back out of our solar system and won’t be coming back. It’s rapidly headed in the direction of the constellation Pegasus and will cross the orbit of Neptune in about four years and cover one light year’s distance in about 11,000 years.

4. We don’t really know what it looks like.

We’ve only seen it as a speck of light through a telescope (it is far away and less than half a mile in length), but its unique rotation leads us to believe that it’s elongated like a cigar, about 10 times longer than it is wide. We can’t see it anymore. Artist’s concepts are the best guesses at what it might look like.

5. We know it got a little speed boost.

A rapid response observing campaign allowed us to watch as 'Oumuamua got an unexpected boost in speed. The acceleration slightly changed its course from earlier predictions.

“This additional subtle force on ′Oumuamua likely is caused by jets of gaseous material expelled from its surface,” said Davide Farnocchia of the Center for Near Earth Object Studies (CNEOS) at NASA’s Jet Propulsion Laboratory. “This same kind of outgassing affects the motion of many comets in our solar system.”

6. We know it’s tumbling.

Unusual variations in the comet’s brightness suggest it is rotating on more than one axis.

This illustration shows ‘Oumuamua racing toward the outskirts of our solar system. As the complex rotation of the object makes it difficult to determine the exact shape, there are many models of what it could look like. Credits: NASA/ESA/STScI

7. We don’t know what it’s made of.

Comets in our solar system kick off lots of dust and gas when they get close to the Sun, but 'Oumuamua did not, which led observers to consider defining it as an asteroid.

Karen Meech, an astronomer at the University of Hawaii’s Institute of Astronomy, said small dust grains, present on the surface of most comets, may have eroded away during ′Oumuamua’s long journey through interstellar space. “The more we study ′Oumuamua, the more exciting it gets.” she said. It could be giving off gases that are harder to see than dust, but it’s impossible to know at this point.

8. We knew to expect it.

Just not when. The discovery of an interstellar object has been anticipated for decades. The space between the stars probably has billions and billions of asteroids and comets roaming around independently. Scientists understood that inevitably, some of these small bodies would enter our own solar system. This interstellar visit by ‘Oumuamua reinforces our models of how planetary systems form.

9. We don’t know what it’s doing now.

After January 2018, ’Oumuamua was no longer visible to telescopes, even in space. But scientists continue to analyze the data gathered during the international observing campaign and crack open more mysteries about this unique interstellar visitor.

10. We know there’s a good chance we’ll see another one…eventually.

Because ′Oumuamua is the first interstellar object ever observed in our solar system, researchers caution that it’s difficult to draw general conclusions about this newly-discovered class of celestial bodies. Observations point to the possibility that other star systems regularly eject small comet-like objects and there should be more of them drifting among the stars. Future ground- and space-based surveys could detect more of these interstellar vagabonds, providing a larger sample for scientists to analyze. Adds, Karen Meech, an astronomer at the University of Hawaii’s Institute of Astronomy: “I can hardly wait for the next interstellar object!“

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This is Kjell Lindgren. He’s a NASA astronaut who just got back from 5 months on the International Space Station. There are two reasons why this picture is hilarious:

His wife is flawless and makes bad space puns to make him do household chores.

I have that shirt. Thousands of people have that shirt. That shirt is available at Target. Which means actual astronaut Kjell Lindgren, with his wardrobe already full of NASA-issued and logo-emblazoned clothes, was at Target, saw a NASA shirt, and was like, “Yes, I am buying this because this is what I want to spend my actual astronaut salary on.”

 tl;dr NASA employs a bunch of fucking nerds

Escape velocities for every planet in the solar system

Cassini's Final Image of Saturn

Here's a mosaic of Saturn made from raw images acquired by Cassini on Sept. 13, 2017, as it was on its way toward its dive into the planet's atmosphere. These images are uncalibrated for color but were acquired in visible-light RGB filters. This will be our last close-up image of Saturn for a long time. Credit: NASA/JPL-Caltech/Space Science Institute/Jason Major

The last look before her descent in fire…

Does all capsules drops in Kazakhstan on return after every mission?

Since the US Space Shuttle retired in 2011, we launch to and return from the Space Station with the Russian Space Agency.  So yes, these capsules (the Soyuz) land in Kazakhstan (or surrounding regions).  However, different spacecrafts have different reentry trajectories, depending on where they aim to land.  As you might recall, the Apollo mission capsules landed in the ocean.  Since Space-X and Boeing are currently building new vehicles so that we will also launch from the US again to get to the International Space Station, these spacecraft will return to the US. For example, you may have seen footage of Space-X cargo vehicles splashing down into the Pacific over the last few years. The Boeing Starliner plans to land on land instead of water. NASA is also currently building the Orion spacecraft, which will take us to destinations beyond low earth orbit (where the Space Station is), whether that be the Moon or Mars or another target.  Orion will also splash down in the ocean.  

Its pretty incredible how accurate the science of astrophysics has gotten. New Horizons actually arrived 72 seconds early after travelling for almost 10 years straight to its destination.

“As the centuries unfold, millions of artists will live on the moon and paint the moon and Mars as we go out into the universe.”

Today we remember the fourth man to walk on the moon. Astronaut Alan Bean passed away in Houston, at the age of 86.

Bean was the lunar module pilot for Apollo 12 in November 1969, and was commander of Skylab 3 in June 1973. He retired from NASA in 1981 to devote his time to painting.

Ep. 11 Satellites, Spacecraft, and Probes - HD and the Void

An overview of the little machines that taught us about our solar system, from Sputnik to future missions into deep space.

An episode late is better than none at all! Hear about satellites, space probes, orbiters, and landers through history. 

Below the cut are sources, music credits, an awesome infographic showing all the satellites currently in orbit around Earth, a vocab list, and the transcript of this episode. 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 in real life. And please check out the podcast on iTunes, rate it or review it if you’d like, subscribe, and maybe tell your friends about it if you think they’d like to listen!

(My thoughts on the next episode were space race history, the transit of Venus, or maybe something about the Moon landing. I’m prepping to interview a friend about her graduate-level research into the history of the universe and possibly dark matter, too. Let me know by the 8th and I’ll hopefully have the next podcast up on September 18th!)

Glossary

Clarke Belt - an area of geostationary orbit in Earth’s atmosphere, 35,786 km directly above the equator, where a satellite orbits the Earth at the same speed the Earth is rotating.

geostationary orbit - when an object orbits directly above the equator and appears stationary to observers on Earth’s surface.

geosynchronous orbit - when an object orbits Earth at an orbital period that matches Earth's rotation on its axis. From the perspective of an observer on Earth's surface, the object would return to the exact same position in the sky after a period of one day.

gyroscopes - a device consisting of several rings that spin freely around different axes. The rapidly rotating wheel has a large moment of inertia and therefore resists change from the plane in which it is rotated. Large gyroscopes allow for steady navigation of ships, submarines, and space ships. See examples in the link.

heliosheath - the outer region of the heliosphere. It is just beyond termination shock, the point where solar wind abruptly slows down and becomes denser and hotter as it presses outward against the approaching wind in interstellar space.

heliosphere - a huge wind sock-shaped bubble that extends beyond Pluto’s orbit and contains our solar system, solar wind, and the entire solar magnetic field.

lander - a spacecraft launched with the intent to land it, unharmed and fully functioning, on the surface of an object that is astronomical in nature. It is aimed at a specific target that astronomers want to learn more about and investigates the object at the surface level. It can be manned or unmanned.

orbiter - an unmanned spacecraft launched with the intent to bring it into orbit around a larger body in order to study that body. It is similar to a satellite but does not orbit Earth.

probe - an unmanned machine sent into space to collect data. It is aimed at a specific target that astronomers want to learn more about.

spacecraft - a pilot-able vehicle used for traveling in space. It can be manned or unmanned.

Van Allen Belts - belts of radiation in Earth’s atmosphere.

Transcript

Sources

Timeline of space exploration to 2013 via the National Archives

Timeline of NASA, the space shuttle, and near-Earth space flights

Space exploration timeline via Sea and Sky

Gyroscope definition via USC

Infographic on satellites launched 1950-1978 via the CalTech Jet Propulsion Lab

List of satellites via Wikipedia

A history of Sputnik via an excerpt from Paul Dickson’s book Sputnik: The Shock of the Century on PBS

“Instead of being concerned with winning the first round of the space race, Eisenhower and his National Security Council were much more interested in launching surveillance satellites that could tell American intelligence where every Soviet missile was located.”

Explorer 1 overview via NASA

Vanguard 1 overview via NASA

SCORE overview via the Smithsonian National Air and Space Museum

Pioneer lunar mission overview via the CalTech Jet Propulsion Lab

Various probe/satellite mission overviews via NASA

Australian WRESAT mission via Australia’s Department of Defence

Pioneer expeditions via NASA

Mariner 10 mission overview via NASA

Magellan mission overview via NASA

Synthetic aperture radar overview via radartutorial.edu

MESSENGER mission overview via JHU Applied Physics Lab

Mariner missions to Venus overview via the CalTech Jet Propulsion Lab

Mariner missions to Mars overview via the CalTech Jet Propulsion Lab

“The final Mariner to Mars, however, was the lab’s greatest planetary success to date.”

Mariner 9 via the CalTech Jet Propulsion Lab

Viking mission overview via NASA

Pathfinder/Sojourner mission overview via NASA

Opportunity mission overview via the CalTech Jet Propulsion Lab

Spirit mission overview via the CalTech Jet Propulsion Lab

Curiosity rover via NASA

Pioneer 10 mission overview via NASA

Pioneer 11 mission overview via NASA

Juno mission overview via the CalTech Jet Propulsion Lab

Cassini-Huygens mission overview via the CalTech Jet Propulsion Lab

Voyager mission overview via the CalTech Jet Propulsion Lab

“The Voyager message is carried by a phonograph record, a 12-inch gold-plated copper disk containing sounds and images selected to portray the diversity of life and culture on Earth.”

Voyager mission trackers via the CalTech Jet Propulsion Lab

Heliosphere definition via NASA

Heliosheath definition via NASA

New Horizons mission overview via NASA

Compton Gamma-Ray Observatory via NASA

Chandra X-Ray Observatory via NASA

Spitzer Space Telescope via CalTech

Einstein Observatory (HEAO-2) via NASA

International Ultraviolet Explorer (IUE) via NASA

International Ultraviolet Explorer (IUE) via ESA

Extreme Ultraviolet Explorer (EUVE) via NASA

Advanced Satellite for Cosmology and Astrophysics (ASCA, formerly ASTRO-D) via NASA archives

Far Ultraviolet Spectroscopic Explorer (FUSE) via JHU

Active space probe/observatory missions via NASA

Chandrayaan-1 via the CalTech Jet Propulsion Lab

Hayabusa 2 mission overview via NASA

Hayabusa-2’s twitter account

A map of every active satellite orbiting Earth via Quartz

Union of Concerned Scientists Satellite Database

Cul-de-Sac comic by Richard Thompson

“Well, there’s dust everywhere, and there’s all kinds of trash—food wrappers and broken parts of things and gloves and shoes. And gas giants and black holes and rocks and dirt. And there’s old TV shows and strange creatures and there’s unidentifiable stuff that no one can explain. And it’s expanding all the time. Toss in a few trillion stuffed toys and it’d be just like your room.”

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

Filler Music: ‘Satellite’ by Guster off their album Ganging Up On The Sun

Filler Music: ‘Sunn’ by Radical Face off his album Sunn Moonn Eclippse. Check out the video in the album link, it’s amazing.

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

NASA has emailed a wrench to astronauts in space

Responding to International Space Station (ISS) astronauts’ need for a wrench, NASA solved the problem by emailing a digital file to the ISS. The astronauts then 3D-printed the tool.

In a post on Backchannel, Mike Chen, founder of Made In Space, explained how the process worked.Made in Space is a Silicon Valley startup that built the 3D printer that was shipped to the ISS in September. In November, the first-ever 3D-printed part was, yes, made in space.

“My colleagues and I just 3D-printed a ratcheting socket wrench on the International Space Station by typing some commands on our computer in California,” Chen wrote in his post. “We had overheard ISS Commander Barry Wilmore … mention over the radio that he needed one, so we designed one in CAD and sent it up to him faster than a rocket ever could have. This is the first time we’ve ever ‘emailed’ hardware to space.”