NASA engineers encoded a secret message in the parachute the Perseverance rover used to slow its descent to the surface of Mars. Tanya Fish provided a handy guide to decoding it on Twitter and as a PDF available on GitHub.
kottke.org posts about Mars
The Secret Message Encoded in the Parachute of the Mars Perseverance Rover
Onboard Camera Views from Perseverance Rover’s Descent & Touchdown on Mars
Just a few days after the Perseverance rover successfully touched down on Mars, NASA has released onboard video from the descent and landing from multiple perspectives. I watched this with my kids last night and all three of us had our mouths hanging open.
The real footage in this video was captured by several cameras that are part of the rover’s entry, descent, and landing suite. The views include a camera looking down from the spacecraft’s descent stage (a kind of rocket-powered jet pack that helps fly the rover to its landing site), a camera on the rover looking up at the descent stage, a camera on the top of the aeroshell (a capsule protecting the rover) looking up at that parachute, and a camera on the bottom of the rover looking down at the Martian surface.
After watching it again just now, I am struck by two things:
- Sometime in my lifetime, live broadcasts from Mars will likely become commonplace. There will be dozens or hundreds of Mars webcams you can pull up on whatever the 2052 internet equivalent is. It will be amazing how boring it all is. (Or perhaps it’ll be boring how amazing it all is.)
- That humans landed on the Moon in 1969 was an incredible feat, but a close second is that the first steps were broadcast live from the Moon’s surface to everywhere on the Earth. Unbelievable.
Can’t wait to see more from Perseverance once the science program gets cranking.
Watch NASA’s Perseverance Rover Land on Mars Live
Today is the day! NASA’s latest Mars rover is scheduled to touch down on the surface of Mars at around 3:55pm EST today1 and you can follow along online. You probably know the drill by now: what you’ll be watching isn’t actually live (it’s delayed by 11 minutes & 22 seconds, the time it takes for data to reach the Earth from Mars) and there’s no video to watch…there’s just telemetry from the rover that indicates where it is and what it’s doing. But I can say having watched the Curiosity landing in 2012, it’s still super exciting and nerve-wracking.
NASA has a number of ways to watch online, including their main stream on YouTube (embedded above), en Español, the “clean feed” from mission control without commentary, and a 360-degree stream, as well as options on Twitter, Facebook, Twitch, etc. You can also watch on NASA TV or through NASA apps on your phone, tablet, or TV. The coverage starts at 2:15pm EST (find your local time) and if all goes well, things start to get exciting at about 3:38pm EST and the landing will happen around 3:55pm EST. To get ready, you can check this page for a schedule of what happens when, watch a video about what’s gonna happen, and look at this live simulated view of where the Perseverance spacecraft is now (here too). Good luck, little rover!
All times in this post (and stated by NASA in their schedules) are when we here on Earth will learn of events after the 11 minute & 22 second informational travel time from Mars is factored in. So while the Mars landing will actually occur around 3:44pm EST, we won’t know about it until 3:55pm EST.↩
The Perseverance Rover Lands on Mars Tomorrow
Curiosity is about to get some company. NASA’s newest rover, Perseverance, is set to land on Mars beginning tomorrow at around 3pm EST. The video above walks us through the 7-minute landing routine in which the rover ditches its spacecraft, heat shields its way through the Martian atmosphere, deploys its parachute, uses an onboard guidance system to navigate to a good landing spot, and finally is lowered down to the surface via a sky crane. The rover’s destination is Jezero Crater, site of an ancient river delta and lakebed.
Jezero Crater tells a story of the on-again, off-again nature of the wet past of Mars. More than 3.5 billion years ago, river channels spilled over the crater wall and created a lake. Scientists see evidence that water carried clay minerals from the surrounding area into the crater lake. Conceivably, microbial life could have lived in Jezero during one or more of these wet times. If so, signs of their remains might be found in lakebed or shoreline sediments. Scientists will study how the region formed and evolved, seek signs of past life, and collect samples of Mars rock and soil that might preserve these signs.
Here’s how you can watch the landing “live” tomorrow (i.e. delayed by the 11 minutes & 22 seconds it takes for signals to travel from Mars). I’ll do a separate post tomorrow w/ the proper YouTube embeds so we can all follow along together.
Gorgeous 4K Video of Mars
To create this ultra HD footage of the surface of Mars, high-definition panoramas created from hundreds of still photos taken by the Mars rovers are panned over using the Ken Burns effect. The end product is pretty compelling — it’s not video, but it’s not not video either.
A question often asked is: ‘Why don’t we actually have live video from Mars?’
Although the cameras are high quality, the rate at which the rovers can send data back to earth is the biggest challenge. Curiosity can only send data directly back to earth at 32 kilo-bits per second.
Instead, when the rover can connect to the Mars Reconnaissance Orbiter, we get more favourable speeds of 2 Megabytes per second.
However, this link is only available for about 8 minutes each Sol, or Martian day.
As you would expect, sending HD video at these speeds would take a long long time. As nothing really moves on Mars, it makes more sense to take and send back images.
(thx, paul)
The Curiosity Rover Captures a 1.8 Gigapixel Panorama of Mars
Late last year, NASA’s Curiosity rover took over a thousand photos of the Martian landscape while exploring a mountainside. NASA stitched the photos together and recently released this 1.8 gigapixel panorama of Mars (along with a mere 650 megapixel panorama, pictured above). Here’s a version you can pan and zoom:
And a narrated video of the panorama:
Both panoramas showcase “Glen Torridon,” a region on the side of Mount Sharp that Curiosity is exploring. They were taken between Nov. 24 and Dec. 1, when the mission team was out for the Thanksgiving holiday. Sitting still with few tasks to do while awaiting the team to return and provide its next commands, the rover had a rare chance to image its surroundings from the same vantage point several days in a row.
I like how NASA is casually suggesting that the rover is just kinda taking some vacation snaps while waiting on friends.
Beautiful Maps of the Solar System’s Asteroids and the Topography of Mercury
Remember how last week I told you about Eleanor Lutz’s An Atlas of Space?
Over the past year and a half I’ve been working on a collection of ten maps on planets, moons, and outer space. To name a few, I’ve made an animated map of the seasons on Earth, a map of Mars geology, and a map of everything in the solar system bigger than 10km.
Well, she’s posted her first two projects: An Orbit Map of the Solar System (a map of more than 18,000 asteroid orbits in the solar system) and A Topographic Map of Mercury.
As promised, Lutz has posted the source code for each project to her GitHub account: Mercury topography, asteroid orbits. What a great resource for aspiring data visualization designers. Stay tuned to her site, Twitter, or Tumblr for upcoming installments of the atlas.
Update: Lutz’s third map in the series is out: The Geology of Mars. And here’s the link to the code and how-to on Github.
Update: Lutz’s fourth map has been released: an animated map of the Earth cycling through all four seasons. Link to the code on GitHub.
Also, she’s made high-res wallpapers available for download in a number of different aspect ratios…check out the links at the bottom of the post.
Update: Today’s installment of the atlas presents a view from our solar system: The Western Constellations (source code on Github).
This week’s map shows every single star visible from Earth, on the darkest night with the clearest sky. The map also includes all of the brightest galaxies, nebulae, and star clusters from W.H. Finlay’s Concise Catalog of Deep-sky Objects. I illustrated the familiar Western star patterns — or asterisms — in blue and gold, as well as the scientific constellation boundaries in red.
Update: Holy moly, I think Lutz’s Topographic Map of Mars might be her most beautiful one yet.
Update: I couldn’t keep up with all of Lutz’s additions to her atlas. You can check out all of the installments in the archive, including the last part (for now), The Geology of the Moon.
The Martian Base in the Gobi Desert
A Chinese company called C-Space has built a simulation of a Mars base in the Gobi desert. Currently used for educational purposes, the company plans to open “Mars Base 1” up for tourism to give visitors a glimpse of what living on Mars would be like.
The facility’s unveiling comes as China is making progress in its efforts to catch up to the United States and become a space power, with ambitions of sending humans to the moon someday.
The white-coloured base has a silver dome and nine modules, including living quarters, a control room, a greenhouse and an airlock.
Alan Taylor featured some photos of Mars Base 1 recently.
It’s all a little surreal, even before you get to the 2001 monolith:
What’s the Weather Like on Mars Right Now?
Now that the InSight lander is up and running on Mars, NASA is using the probe’s weather instrumentation to provide a daily weather report from the red planet.
The report is delayed by a day or so (communications delay? non-essential data delay?), but it’s still really cool to see what the temperature, wind speed, and barometric pressure is at Elysium Planitia.
I’d just like to note for the record that at some point on Monday, it was actually warmer on Mars than it is right now in Vermont. ♫ Gotta get up, gotta get out, gotta get out into the Martian sun… ♫
Goodbye Opportunity, the Little Mars Rover that Could
Yesterday, NASA declared the official end to the Opportunity rover mission on Mars.
One of the most successful and enduring feats of interplanetary exploration, NASA’s Opportunity rover mission is at an end after almost 15 years exploring the surface of Mars and helping lay the groundwork for NASA’s return to the Red Planet.
The Opportunity rover stopped communicating with Earth when a severe Mars-wide dust storm blanketed its location in June 2018. After more than a thousand commands to restore contact, engineers in the Space Flight Operations Facility at NASA’s Jet Propulsion Laboratory (JPL) made their last attempt to revive Opportunity Tuesday, to no avail. The solar-powered rover’s final communication was received June 10.
Opportunity was the longest-lived robot ever sent to another planet; it lasted longer than anyone could have imagined.
Designed to last just 90 Martian days and travel 1,100 yards (1,000 meters), Opportunity vastly surpassed all expectations in its endurance, scientific value and longevity. In addition to exceeding its life expectancy by 60 times, the rover traveled more than 28 miles (45 kilometers) by the time it reached its most appropriate final resting spot on Mars — Perseverance Valley.
Here’s a quick video overview of the milestones of Opportunity’s mission:
The NY Times has a great interactive feature about the rover’s activities and achievements and XKCD has a tribute.
A Massive Ice-Filled Crater on Mars
ESA’s Mars Express mission recently photographed the Korolev crater on Mars, filled almost to the brim with water ice.1 When I first saw this image I thought, oh cute!, assuming the crater was maybe a few dozen feet across. But no, it’s about 51 miles across and the thickest part of the ice is over a mile thick.
This ever-icy presence is due to an interesting phenomenon known as a ‘cold trap’, which occurs as the name suggests. The crater’s floor is deep, lying some two kilometres vertically beneath its rim.
The very deepest parts of Korolev crater, those containing ice, act as a natural cold trap: the air moving over the deposit of ice cools down and sinks, creating a layer of cold air that sits directly above the ice itself.
Behaving as a shield, this layer helps the ice remain stable and stops it from heating up and disappearing. Air is a poor conductor of heat, exacerbating this effect and keeping Korolev crater permanently icy.
Update: Just to clarify slightly, the top image was generated using photographs taken by Mars Express and a terrain map, so it’s technically not a photograph but is like the oblique view in Google Maps. The bottom image is a composite of five photographs. (via @ryanguill)
Mars also has CO2 ice, so you have to specify.↩
Hear the First Sounds Ever Recorded on Mars
NASA’s InSight mission recently landed on Mars and like other missions before it, the lander is a equipped with a camera and has sent back some pictures of the red planet. But InSight is also carrying a couple of instruments that made it possible to record something no human has ever experienced: what Mars sounds like:
InSight’s air pressure sensor recording the sound of the wind directly and the seismometer recorded the sounds of the lander’s solar panels vibrating as Martian winds blew across them.
Two very sensitive sensors on the spacecraft detected these wind vibrations: an air pressure sensor inside the lander and a seismometer sitting on the lander’s deck, awaiting deployment by InSight’s robotic arm. The two instruments recorded the wind noise in different ways. The air pressure sensor, part of the Auxiliary Payload Sensor Subsystem (APSS), which will collect meteorological data, recorded these air vibrations directly. The seismometer recorded lander vibrations caused by the wind moving over the spacecraft’s solar panels, which are each 7 feet (2.2 meters) in diameter and stick out from the sides of the lander like a giant pair of ears.
The sounds are best heard with a good pair of headphones.
Love Letters to Mars
Rebecca Boyle is one of my favorite science writers. In two recent pieces, she takes on our nearest, most Earth-like neighbor, Mars. The first is about a team of scientists doing research on extremophiles in South America.
The Atacama Desert stretches 600 miles south from the Peruvian border, nestled between the Pacific Cordillera and the Andes, “a cross extended over Chile,” in the words of the Chilean poet Raúl Zurita. Some parts of it are so devoid of life that their microbe-per-inch count can compete with near-sterile hospital surgical suites. Some areas of the Atacama, Earth’s driest nonpolar desert and the oldest desert anywhere, have been rainless for at least 23 million years, and maybe as long as 40 million years. Carbon cycling happens on timescales of thousands of years, comparable to Antarctic permafrost and places deep within Earth’s crust; the Atacama contains some of the most lifeless soils on the planet. The Atacama is one reason that Chile has become a haven for astrobiologists and astronomers: Its pristine dark skies offer an unparalleled view of the stars, and its depleted desert offers a peerless lab for studying the dry limits of life, including how life might survive among those stars. And honestly, it just looks a lot like Mars. It is the closest that these astrobiologists will ever get to the planet that occupies their grant proposals and their imaginations.
I’m neither an astrobiologist nor a professional astronomer, but I spend a lot of time thinking about Mars. I keep tabs on the robots spread across its surface and in its orbit, and sometimes I check their nightly photo downloads. The Atacama is not a giant leap from the Mars of my mind. As I drove up the coast, I found the view so much more like Mars than Earth. There are no palm trees or tourists or bleating gulls. There is nothing but brown, tumbling tanly down the hills, darkening to chocolate inside shadowy ravines and runnels, bleaching to an impoverished shade of cardboard, and crumbling into fine white beach before being swallowed by the cobalt hues of sea and sky. With no trees or succulents or even a blade of grass—not a smidge of green—the only disruption in the brown is a strip of asphalt, Ruta 1. With my cruise control set and David Bowie blaring, I pictured myself driving through Meridiani Planum, a vast equatorial Martian plain, en route to visit the Opportunity rover. The only reminders of other humans were the grim commemorations of car-wreck victims: Almost every mile of Ruta 1 is marked with roadside shrines to the dead…
Salar Grande was once a coastal inlet, much like today’s San Francisco Bay. It dried up between 1.8 and 5.3 million years ago, leaving behind a salt flat between 225 and 300 feet thick. The salar is therefore an analogue for the last time Mars was habitable, after Mars’ oceans, if there were any, dried up, when Martian ecosystems became concentrated in smaller places. And, like Mars itself, the Atacama is a glimpse into Earth’s own future. One day, billions of years from now, all of Earth may resemble this parched land of fissures and knobs, after our own oceans boil away, after the last trees fall, after the algae are all that is left of us.
“In the beginning,” Davila said, “there was bacteria. And at the end, there will be bacteria.”
The second piece is literally a letter, written to the Curiosity Rover that’s explored the red planet since 2012.
I think of you often. For much of this year, I saw Mars shining red in the window right above my computer. It was nice, like keeping an eye on you. And when I went to Mars earlier this year—actually the Atacama, a desert at the bottom of this world—the landscape made me think of you a lot. It made me grateful for the Mars you gave me, the Mars of my mind. Even more than your forebears did, you helped me understand why Mars stands out among the planets.
Earth’s other neighbors are interesting, sure. Jupiter is a peach-and-tan inkwell stirred with gothic darkness. Saturn and its orrery of moons trace feverish circles, as if brushed onto the void by the painter Kandinsky. Uranus and Neptune are the plain Christmas ornaments I hang next to the ornate ones, just to make the tree seem less busy. Mercury is a purple version of the moon, and Venus is a blast-furnace hellscape.
But Mars, little red Mars—it’s just like home. When you gaze out on the Murray Buttes, I see my Rocky Mountains.
That Mars — so like our world, yet so unlike it. Like a lover who understands and compliments us through similarity amid difference. It may be in the distance, but it is next.
And its visitors, like Curiosity, are already our friends:
I admire Juno’s photos of Jupiter and Cassini’s photos of Saturn, sure, but I don’t see the spacecraft in those images. And that means I don’t see myself. My connection to Mars comes from seeing you there. Seeing the terrain as you see it, that’s wonderful—but seeing you seeing it, feeling the photographer’s undeniable presence, is transformative.
Update: Boyle wrote a coda to her two pieces on Mars today for Last Word on Nothing. It’s Earth-focused, but then again, Earth is a very strange planet too:
At one point, after a couple hours of driving south, I needed a break. I needed to smell the ocean, mere feet to my right. I pulled over to the shoulder, parked my silver SUV on the sand, and walked a few feet. I was completely on my own. I saw nothing alive—no gull, no driver, no seaweed, no plant. I stared at the Pacific and felt my chest tighten. I was thousands of miles from my family, and I have never felt more alone.
The ocean was loud, dashing against dark rocks, and within a minute I felt like its rhythm was a part of me. It was going to swallow me and the sun was going to drive me mad. I strained to see anything else alive, some sign that I was still on Earth, but I saw nothing but sand and blue.
I squinted for a minute. The entire planet looks like this, from a great distance. From the Moon, you can make out the continents, patches of brown and green beneath a light frosting of clouds. But the general impression of Earth is one of blue and white. Ocean and sky. Our blue marble.
I listened to the Pacific and took a step forward. I was on Earth. I was so lucky to be here. So goddamn lucky I suddenly wanted to scream. Do you know how rare it is to have a planet covered in water? How precious it is to get out of the car, walk a few feet, and touch the ocean? It was the deep blue of my daughter’s eyes. This water is flowing through me, through her, through all of us here, together. Is this enlightenment? I thought to myself. I don’t know enough about Buddhism.
It was hard to get back in the car after that. But I feared that if I didn’t, the Pacific would rise up and consume me, swallow me whole before I had a chance to tell anyone I saw it. I had to tell her what I saw.
Watch It Live: NASA’s InSight Probe Lands on Mars Today
After a seven-month journey covering over 300 million miles, NASA’s InSight probe will land on the surface of Mars today around 3pm. The video embedded above is a live stream of mission control at NASA’s Jet Propulsion Laboratory that starts at 2pm and will be the best thing to watch as the probe lands. (See also this live stream of NASA TV.) The landing will occur around 2:47pm ET but the landing signal from Mars won’t arrive on Earth until 2:54pm ET at the earliest. And no video from the landing itself of course…”live” is a bit of a misnomer here but it still should be exciting.
NASA produced this short video that shows what’s involved in the landing process, aka how the probe goes from doing 13,000 mph to resting on the surface in just six-and-a-half minutes.
The NY Times has a good explainer on the InSight mission and landing.
NASA’s study of Mars has focused on the planet’s surface and the possibility of life early in its history. By contrast, the InSight mission — the name is a compression of Interior Exploration Using Seismic Investigations, Geodesy and Heat Transport — will study the mysteries of the planet’s deep interior, aiming to answer geophysical questions about its structure, composition and how it formed.
I love this stuff…the kids and I will be watching for sure!
Update: The Oatmeal has a great comic about the InSight landing.
Law & Order: Martian Victims Unit
I loved this imaginative and clever piece by Geoff Manaugh called How Will Police Solve Murders on Mars? about how a future human settlement on Mars would handle matters of law and order. For one things, crimes might be more difficult to investigate.
Consider the basic science of crime-scene analysis. In the dry, freezer-like air and extreme solar exposure of Mars, DNA will age differently than it does on Earth. Blood from blunt-trauma and stab wounds will produce dramatically new spatter patterns in the planet’s low gravity. Electrostatic charge will give a new kind of evidentiary value to dust found clinging to the exteriors of space suits and nearby surfaces. Even radiocarbon dating will be different on Mars, Darwent reminded me, due to the planet’s atmospheric chemistry, making it difficult to date older crime scenes.
The Martian environment itself is also already so lethal that even a violent murder could be disguised as a natural act. Darwent suggested that a would-be murderer on the Red Planet could use the environment’s ambient lethality to her advantage. A fatal poisoning could be staged to seem as if the victim simply died of exposure to abrasive chemicals, known as perchlorates, in the Martian rocks. A weak seal on a space suit, or an oxygen meter that appears to have failed but was actually tampered with, could really be a clever homicide hiding in plain sight.
At a broader level, what sort of political system develops because of the Martian environment might shape how law enforcement happens.
In the precarious Martian environment, where so much depends on the efficient, seamless operation of life-support systems, sabotage becomes an existential threat. A saboteur might tamper with the oxygen generators or fatally disable a settlement’s most crucial airlock. When human life is so thoroughly entwined with its technical environment, we should not consider these sorts of acts mere petty crimes, he explained to me. In a literal sense, they would be crimes against humanity-even, on a large enough scale, attempted genocide.
“I think the fact that tyranny is easier in space is a foregone conclusion,” he explained to me, precisely because there is nowhere to escape without risking instant death from extreme cold or asphyxiation. In other words, the constant presence of nearly instant environmental lethality will encourage systems of strong social control with little tolerance for error. Orders and procedures will need to be followed exactly as designed, because the consequences of a single misstep could be catastrophic.
A few paragraphs after this, the terrifyingly wonderful phrase “politically motivated depressurization” is used. I don’t think we’re super close to the colonization of Mars, but Manaugh says, better to think about it now before we “unwittingly construct an interplanetary dystopia run by cops who shoot first and ask questions later”.
Photos from the Curiosity rover’s 2000 days on Mars
NASA’s Curiosity rover has been on Mars for more than 2000 days now, and it has sent back over 460,000 images of the planet. Looking at them, it still boggles the mind that we can see the surface of another planet with such clarity, like we’re looking out the window at our front yard. Alan Taylor has collected a bunch of Curiosity’s photos from its mission, many of which look like holiday snapshots from the rover’s trip to the American Southwest.
SpaceX wants to send people to Mars by 2024
Elon Musk says SpaceX is on target to send cargo to Mars in 2022 and people in 2024. The way the company will do it is by focusing its resources on a new vehicle, the Interplanetary Transport System (codename: the BFR). That vehicle will be able to travel to Mars, but can also be used to generate revenue for the company through launching satellites, resupplying the ISS, and going to the Moon.
Musk also proposed a variety of new uses for the scaled-down rocket beyond just going to Mars. Supposedly, the ITS can be used to launch satellites, take cargo to the International Space Station, and even do lunar missions to set up a Moon base. SpaceX’s current Falcon 9 fleet is used to do a few of those things already, but Musk says eventually the company will turn to the ITS to do all of its space missions.
“We can build a system that cannibalizes our own products, makes our own products redundant, then all the resources we use for Falcon Heavy and Dragon can be applied to one system,” he said at the conference. Musk says the cost of launching cargo on the ITS will be fairly cheap, too, since the rocket and spaceship will be a fully reusable system — unlike the Falcon 9, which is only 70 to 80 percent reusable.
Musk also astoundingly asserted that the same rocket system could be used for long-distance travel on Earth.
He ended his talk with a pretty incredible promise: using that same interplanetary rocket system for long distance travel on Earth. Musk showed a demonstration of the idea on stage, claiming that it will allow passengers to take “most long distance trips” in just 30 minutes, and go “anywhere on Earth in under an hour” for around the same price of an economy airline ticket.
As they say, “huge if true”. Musk is like the sci-fi Oprah here: You get a electric car! And you get a trip to Mars! And you get a self-driving car! And you get a 30-minute Hyperloop trip from SF to LA! And you get a rocket shuttle from NYC to Mumbai in 43 minutes for $1200! Beeeeeeeeees!!!!
A tour of our solar system’s eclipses
In a meditative video for the NY Times, Dennis Overbye takes us on a tour of eclipses that happen in our solar system and beyond.
On the 21st day of August, 2017, the moon will slide between the Earth and the sun, painting a swath of darkness across North America. The Great American Solar Eclipse. An exercise in cosmic geometry. A reminder that we live on one sphere among many, all moving to the laws of Kepler, Newton and Einstein.
Humans have many more vantage points from which to observe solar eclipses than when the last solar eclipse occurred in the US in 1979. I had no idea that the Mars rovers had caught partial solar eclipses on Mars…so cool. (via @jossfong)
The view from Mars
NASA’s Opportunity rover started exploring the surface of Mars in January 2004. Its mission was supposed to last about 90 days, but over 13 years later, Opportunity is still rolling around the red planet, doing science and taking photos. Jason Major processed a few of Opportunity’s most recent snaps of the Endeavour Crater and they’re just wonderful. I’m especially taken with the one included above…it belongs in a museum!
A fictional flight above real Mars
Using real images of Mars taken by the HiRISE camera on the Mars Reconnaissance Orbiter, Jan Fröjdman created a 3D-rendered flyover of several areas of the planet’s surface.
In this film I have chosen some locations and processed the images into panning video clips. There is a feeling that you are flying above Mars looking down watching interesting locations on the planet. And there are really great places on Mars! I would love to see images taken by a landscape photographer on Mars, especially from the polar regions. But I’m afraid I won’t see that kind of images during my lifetime.
It has really been time-consuming making these panning clips. In my 3D-process I have manually hand-picked reference points on the anaglyph image pairs. For this film I have chosen more than 33.000 reference points! It took me 3 months of calendar time working with the project every now and then.
Watch this in the highest def you can muster…gorgeous.
Musk: SpaceX will start colonizing Mars in 7 years
Yesterday, Elon Musk shared SpaceX’s plan for colonizing Mars. Gizmodo has a good overview of the plan.
SpaceX plans to build a “self-sustaining city” on Mars, according to its founder Elon Musk. But, while we now know a lot more about how SpaceX plans to get to Mars, details about how people will actually survive up there remain sketchy.
Musk dropped the news on Tuesday during an address at the International Astronautical Congress meeting in Guadalajara, Mexico, where he had promised to reveal how the company planned to send people to live on Mars.
“I don’t have an immediate doomsday prophecy,” said Musk, but he noted that he saw only two possible paths forward. “One path is to stay on Earth forever, and there will be some extinction event. The alternative is to become a multi-planetary species, which I hope you will agree is the right way to go.”
Musk says that human flights to Mars could start as soon as 2023. So audacious, I love it. I am so rooting for him to pull this off.
Update: Wait But Why has a characteristically entertaining and informative piece about SpaceX’s Big Fucking Rocket.
“It’s so mind-blowing. It blows my mind, and I see it every week.”
Elon’s pumped. And when you learn about the big fucking rocket he’s building, you’ll understand why.
First, let’s absorb the challenge at hand. It’s often said that space is hard. To this day, only a few hundred people have been in space, only a few countries have the ability to launch something into space, and the history of human space travel is littered with tragic launch failures. Firing something super heavy and delicate and full of explosive liquid up through the atmosphere without anything going wrong is incredibly hard.
But when we talk about humans going into space, we’re talking mostly about humans going into Low Earth Orbit, a layer of space between 100 and 1,200 miles above the ground — and normally, they’re headed only 250 miles up to the International Space Station. The only time humans have gone farther were the small handful of Americans who made it out to the moon in the 1960s, traveling about 250,000 miles away.
When Earth and Mars are at their closest, Mars is somewhere between 34 and 60 million miles away — about 200 times farther away than the moon and about 200,000 times farther away than the ISS.
The moon is just over one light second away.
Mars is more than three light minutes away.
Mars is far.
NASA extends the missions of nine spacecraft
While we’re on the subject, NASA announced late last week that they are extending the missions of nine spacecraft sprinkled about the solar system. Included are the New Horizon probe, which will wing off to study an object in the Kuiper Belt after doing so well with Pluto and the rover Opportunity, which was slated for a mission lasting just over 90 days but has now spent more than 12 years exploring the surface of Mars.
The Dawn mission to Ceres is another spacecraft whose duration has been extended, beating long odds. Part of the spacecraft’s functionality had not been working for some time, but was recently repaired.
It was a bit unexpected because Dawn is low on fuel. “Less than a year ago, I would have thought it was ridiculous that the spacecraft would even be operating at this point,” said Marc D. Rayman, the chief engineer for the Dawn mission.
The Dawn spacecraft was designed to use four spinning wheels to pivot in different directions. But at its previous destination, the asteroid Vesta, two of the four wheels overheated and failed. At Ceres, the wheels stayed off, and the spacecraft used its thrusters instead to pivot.
In December, Dawn reached its lowest orbit, just 240 miles above Ceres. Dr. Rayman said he and his team had expected Dawn to exhaust its remaining propellant by March.
But they spun up the wheels again. That succeeded, cutting the use of the thrusters. “It all worked out beautifully,” Dr. Rayman said. That left enough fuel to contemplate doing something more.
Medieval-style map of Mars
From Eleanor Lutz, a gorgeous medieval-style map of Mars.
This is what it looks like to land on Mars
When the Curiosity rover landed on the surface of Mars, it took high-resolution photos all the way down. Luke Fitch took those photos and stitched them together into a first-person HD video of the rover’s landing.
Update: I was wondering if someone had done a stabilized version of this video and lo:
(via @willhains)
NASA: there’s liquid water on the surface of Mars
NASA’s press conference doesn’t start for a few minutes yet, but the NY Times has the scoop: NASA has found “definitive signs” of liquid water on the surface of Mars. Like, right now on Mars, not millions of years ago.
In a paper published in the journal Nature Geoscience, Dr. McEwen and other scientists identified waterlogged molecules — salts of a type known as perchlorates - in readings from orbit.
“That’s a direct detection of water in the form of hydration of salts,” Dr. McEwen said. “There pretty much has to have been liquid water recently present to produce the hydrated salt.”
By “recently,” Dr. McEwen said he meant “days, something of that order.”
This is fantastic timing for the release of The Martian movie, which comes out this weekend.
Update: And here’s the official press release from NASA.
“Our quest on Mars has been to ‘follow the water,’ in our search for life in the universe, and now we have convincing science that validates what we’ve long suspected,” said John Grunsfeld, astronaut and associate administrator of NASA’s Science Mission Directorate in Washington. “This is a significant development, as it appears to confirm that water — albeit briny — is flowing today on the surface of Mars.”
These downhill flows, known as recurring slope lineae (RSL), often have been described as possibly related to liquid water. The new findings of hydrated salts on the slopes point to what that relationship may be to these dark features. The hydrated salts would lower the freezing point of a liquid brine, just as salt on roads here on Earth causes ice and snow to melt more rapidly. Scientists say it’s likely a shallow subsurface flow, with enough water wicking to the surface to explain the darkening.
Explore Mars from the comfort of your office
What are you doing today Jason? Oh not much just exploring Mars. The hell you say. Like fun I am! NASA has released a pair of web apps: one lets you drive Curiosity around the surface of Mars and the other is a 3D visualization of the planet. Oh cool that’s what I’m doing today now too. And when you’re done with that, follow NASA’s new Tumblr. Far out man.
Compasses don’t work on Mars, so how do you navigate?
Unlike the Earth, Mars and the Moon don’t have strong directional magnetic fields, which means traditional compasses don’t work. So how did the Apollo rovers and current Mars rovers navigate their way around? By using manually set directional gyroscope and wheel odometers.
While current un-crewed rovers don’t have to return to the comfort of a lunar module, some aspects of the Apollo systems live on in their design. Four U.S. Martian rovers have used wheel odometers that account for slippage to calculate distance traveled. They’ve also employed gyroscopes (in the form of an inertial measurement units) to determine heading and pitch/roll information.
One of the fun things about reading The Martian is you get to learn a little bit about this sort of thing. Here’s a passage about navigation on Mars where astronaut Mark Watney is trying to get to a landmark several days’ drive away.
Navigation is tricky.
The Hab’s nav beacon only reaches 40 kilometers, so it’s useless to me out here. I knew that’d be an issue when I was planning this little road trip, so I came up with a brilliant plan that didn’t work.
The computer has detailed maps, so I figured I could navigate by landmarks. I was wrong. Turns out you can’t navigate by landmarks if you can’t find any god damned landmarks.
Our landing site is at the delta of a long-gone river . NASA chose it because if there are any microscopic fossils to be had, it’s a good place to look. Also, the water would have dragged rock and soil samples from thousands of kilometers away. With some digging, we could get a broad geological history.
That’s great for science, but it means the Hab’s in a featureless wasteland.
I considered making a compass. The rover has plenty of electricity, and the med kit has a needle. Only one problem: Mars doesn’t have a magnetic field.
So I navigate by Phobos. It whips around Mars so fast it actually rises and sets twice a day, running west to east. It isn’t the most accurate system, but it works.
I wonder why the rovers in the story weren’t outfitted with directional gyroscopes and wheel odometers? (See also the operations manual for the lunar rovers.) (via @JaredCrookston)
Curiosity: stronger support for life on Mars
Whilst roving about Mars, Curiosity has slowly but surely racked up evidence for a past Mars that was warm, wet, and possibly habitable.
John P. Grotzinger of Caltech, the project scientist for the mission, reported at a news conference on Monday that the rover’s yearlong trek to Mount Sharp provided strong new evidence that Gale Crater had large lakes, rivers and deltas, on and off, for millions to tens of millions of years. The geology shows that even when the surface water dried up, plenty of water would have remained underground, he said.
Moreover, the team concluded, numerous deltalike and lakelike formations detected by orbiting satellites are almost certainly the dried remains of substantial ancient lakes and deltas. None of this proves that life existed on the planet, but the case for an early Mars that was ripe and ready for life has grown stronger.
“As a science team, Mars is looking very attractive to us as a habitable planet,” Dr. Grotzinger said in an interview. “Not just sections of Gale Crater and not just a handful of locations, but at different times around the globe.”
See also the interactive 28 Months on Mars.
Update: And right on cue, Curiosity has recorded a two-month-long methane burst on Mars. One explanation for the methane is that it’s a waste product of living organisms.
The presence of methane is significant because the gas cannot exist for long. Calculations indicate that sunlight and chemical reactions in the Martian atmosphere would break up the molecules within a few hundred years, so any methane there now must have been created recently.
It could have been created by a geological process known as serpentinization, which requires both heat and liquid water. Or it could be a product of life in the form of microbes known as methanogens, which release methane as a waste product.
Even if the explanation for the methane turns out to be geological, the hydrothermal systems would still be prime locations to search for signs of life.
Update: And now Curiosity has found “biologically useful nitrogen” on Mars.
There is no evidence to suggest that the fixed nitrogen molecules found by the team were created by life. The surface of Mars is inhospitable for known forms of life. Instead, the team thinks the nitrates are ancient, and likely came from non-biological processes like meteorite impacts and lightning in Mars’ distant past.
Features resembling dry riverbeds and the discovery of minerals that form only in the presence of liquid water suggest that Mars was more hospitable in the remote past. The Curiosity team has found evidence that other ingredients needed for life, such as liquid water and organic matter, were present on Mars at the Curiosity site in Gale Crater billions of years ago.
“Finding a biochemically accessible form of nitrogen is more support for the ancient Martian environment at Gale Crater being habitable,” said Jennifer Stern of NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
Update: The analysis of a year of weather and soil data collected by Curiosity indicates that a small amount of liquid water could exist below the surface of Mars.
Martian weather and soil conditions that NASA’s Curiosity rover has measured, together with a type of salt found in Martian soil, could put liquid brine in the soil at night.
Perchlorate identified in Martian soil by the Curiosity mission, and previously by NASA’s Phoenix Mars Lander mission, has properties of absorbing water vapor from the atmosphere and lowering the freezing temperature of water. This has been proposed for years as a mechanism for possible existence of transient liquid brines at higher latitudes on modern Mars, despite the Red Planet’s cold and dry conditions.
New calculations were based on more than a full Mars year of temperature and humidity measurements by Curiosity. They indicate that conditions at the rover’s near-equatorial location were favorable for small quantities of brine to form during some nights throughout the year, drying out again after sunrise. Conditions should be even more favorable at higher latitudes, where colder temperatures and more water vapor can result in higher relative humidity more often.
The Guardian and other media outlets have translated this news into Nasa’s Curiosity rover finds water below surface of Mars even though NASA’s release clearly states “we have not detected brines”. Come on, guys.
The meteorite collector
A weight-loss doctor from Indiana owns a surprising number of the world’s known meteorites, including about 2/3s of an unusual Martian meteorite called Black Beauty, which is valued at more than $10,000 per gram.
There is one diva in particular that I’m here to pay homage to: Black Beauty, a shiny, scaly-skinned, 4.4-billion-year-old rock from Mars. It began its journey to Earth more than 5 million years ago, about the time humans and chimpanzees were splitting from a common ancestor. That is when an asteroid struck Mars, catapulting the rock into space. Sometime in the last thousand years or so, orbital mechanics and gravity delivered the wandering rock to Earth. Surviving an incendiary plunge through the atmosphere, it landed in more than a dozen pieces in the western Sahara. There the fragments sat, untouched except by wind and sand. Finally, a nomad plucked a piece from the dunes. After passing through the hands of several Moroccan middlemen, the first piece wound up in Piatek’s hands in 2011. He would acquire nine more.
Black Beauty has since set the collecting world on fire, reaching values of more than $10,000 per gram. (Gold trades for $40 per gram.) The price is in no small part due to the parade of scientific discoveries emerging from the rock’s jumbled-up guts. It is the oldest rock from Mars and chock-full of the planet’s primordial water. Most intriguing of all, it appears to be the first martian meteorite made of sediment, deposited by wind or water. That makes Black Beauty not only a cosmic blessing-sedimentary rocks are fragile and thought unlikely to survive interplanetary launches-but also a boon for astrobiologists. “If you’re going to look for life, you want a sedimentary rock,” says Munir Humayun, a meteoriticist at Florida State University in Tallahassee who led a study that last year pinpointed the rock’s age.
The size of astronomy stuff
It can be difficult to understand how large (or small) astronomical objects are, so here are some handy comparisons to things on Earth. Here’s the size of Mars compared to the United States & Canada:
And here’s a neutron star nestled next to Liverpool on the northwest coast of England:
A neutron star also crams in over 1.5 times the mass of the Sun into a tiny ball maybe not much bigger than your daily commute to work, and the Sun is huge (see the size of the Sun later). So this thing is incredibly dense, so dense in fact that just a tea spoon of it would weigh over a billion tonnes, and if you could stand on its surface you’d feel the gravitational pull of 200 billion times that of our planet…not that you’d ever survive it of course.
(via @theclintmcleod)