"The towers of fiery colors are actually dust in the galaxy and beyond that has been polarized," the JPL says of this recently released map of the universe. It shows light in the 353GHz range, wavelengths longer than our eyes can see. ...
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When Falcon Heavy lifts off later this year, it will be the most powerful operational rocket in the world by a factor of two. Thrust at liftoff is equal to approximately eighteen 747 aircraft operating simultaneously. Excerpt from csmonitor.com...
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In this infrared image, stellar winds from a giant star cause interstellar dust to form ripples. There's a whole lot of dust—which contains oxygen, carbon, iron, nickel, and all the other elements—out there, and eventually some of it finds its way into our bodies. Photograph by NASA, JPL-Caltech |
We have stardust in us as old as the universe—and some that may have landed on Earth just a hundred years ago.
Excerpt from National Geographic
By Simon Worrall
Astrophysics and medical pathology don't, at first sight, appear to have much in common. What do sunspots have to do with liver spots? How does the big bang connect with cystic fibrosis?
Book jacket courtesy of schrijver+schrijver
Astrophysicist Karel Schrijver, a senior fellow at the Lockheed Martin Solar and Astrophysics Laboratory, and his wife, Iris Schrijver, professor of pathology at Stanford University, have joined the dots in a new book, Living With the Stars: How the Human Body Is Connected to the Life Cycles of the Earth, the Planets, and the Stars.
Talking from their home in Palo Alto, California, they explain how everything in us originated in cosmic explosions billions of years ago, how our bodies are in a constant state of decay and regeneration, and why singer Joni Mitchell was right.
"We are stardust," Joni Mitchell famously sang in "Woodstock." It turns out she was right, wasn't she?
Iris: Was she ever! Everything we are and everything in the universe and on Earth originated from stardust, and it continually floats through us even today. It directly connects us to the universe, rebuilding our bodies over and again over our lifetimes.
That was one of the biggest surprises for us in this book. We really didn't realize how impermanent we are, and that our bodies are made of remnants of stars and massive explosions in the galaxies. All the material in our bodies originates with that residual stardust, and it finds its way into plants, and from there into the nutrients that we need for everything we do—think, move, grow. And every few years the bulk of our bodies are newly created.
Can you give me some examples of how stardust formed us?
Karel: When the universe started, there was just hydrogen and a little helium and very little of anything else. Helium is not in our bodies. Hydrogen is, but that's not the bulk of our weight. Stars are like nuclear reactors. They take a fuel and convert it to something else. Hydrogen is formed into helium, and helium is built into carbon, nitrogen and oxygen, iron and sulfur—everything we're made of. When stars get to the end of their lives, they swell up and fall together again, throwing off their outer layers. If a star is heavy enough, it will explode in a supernova.
So most of the material that we're made of comes out of dying stars, or stars that died in explosions. And those stellar explosions continue. We have stuff in us as old as the universe, and then some stuff that landed here maybe only a hundred years ago. And all of that mixes in our bodies.
Stars are being born and stars are dying in this infrared snapshot of the heavens. You and I—we come from stardust.
Photograph by NASA, JPL-Caltech, University of Wisconsin
Your book yokes together two seemingly different sciences: astrophysics and human biology. Describe your individual professions and how you combined them to create this book.
Iris: I'm a physician specializing in genetics and pathology. Pathologists are the medical specialists who diagnose diseases and their causes. We also study the responses of the body to such diseases and to the treatment given. I do this at the level of the DNA, so at Stanford University I direct the diagnostic molecular pathology laboratory. I also provide patient care by diagnosing inherited diseases and also cancers, and by following therapy responses in those cancer patients based on changes that we can detect in their DNA.
Our book is based on many conversations that Karel and I had, in which we talked to each other about topics from our daily professional lives. Those areas are quite different. I look at the code of life. He's an astrophysicist who explores the secrets of the stars. But the more we followed up on our questions to each other, the more we discovered our fields have a lot more connections than we thought possible.
Karel: I'm an astrophysicist. Astrophysicists specialize in all sorts of things, from dark matter to galaxies. I picked stars because they fascinated me. But no matter how many stars you look at, you can never see any detail. They're all tiny points in the sky.
So I turned my attention to the sun, which is the only star where we can see what happens all over the universe. At some point NASA asked me to lead a summer school for beginning researchers to try to create materials to understand the things that go all the way from the sun to the Earth. I learned so many things about these connections I started to tell Iris. At some point I thought: This could be an interesting story, and it dawned on us that together we go all the way, as she said, from the smallest to the largest. And we have great fun doing this together.
We tend to think of our bodies changing only slowly once we reach adulthood. So I was fascinated to discover that, in fact, we're changing all the time and constantly rebuilding ourselves. Talk about our skin.
Iris: Most people don't even think of the skin as an organ. In fact, it's our largest one. To keep alive, our cells have to divide and grow. We're aware of that because we see children grow. But cells also age and eventually die, and the skin is a great example of this.
It's something that touches everything around us. It's also very exposed to damage and needs to constantly regenerate. It weighs around eight pounds [four kilograms] and is composed of several layers. These layers age quickly, especially the outer layer, the dermis. The cells there are replaced roughly every month or two. That means we lose approximately 30,000 cells every minute throughout our lives, and our entire external surface layer is replaced about once a year.
Very little of our physical bodies lasts for more than a few years. Of course, that's at odds with how we perceive ourselves when we look into the mirror. But we're not fixed at all. We're more like a pattern or a process. And it was the transience of the body and the flow of energy and matter needed to counter that impermanence that led us to explore our interconnectedness with the universe.
You have a fascinating discussion about age. Describe how different parts of the human body age at different speeds.
Iris: Every tissue recreates itself, but they all do it at a different rate. We know through carbon dating that cells in the adult human body have an average age of seven to ten years. That's far less than the age of the average human, but there are remarkable differences in these ages. Some cells literally exist for a few days. Those are the ones that touch the surface. The skin is a great example, but also the surfaces of our lungs and the digestive tract. The muscle cells of the heart, an organ we consider to be very permanent, typically continue to function for more than a decade. But if you look at a person who's 50, about half of their heart cells will have been replaced.
Our bodies are never static. We're dynamic beings, and we have to be dynamic to remain alive. This is not just true for us humans. It's true for all living things.
A figure that jumped out at me is that 40,000 tons of cosmic dust fall on Earth every year. Where does it all come from? How does it affect us?
Karel: When the solar system formed, it started to freeze gas into ice and dust particles. They would grow and grow by colliding. Eventually gravity pulled them together to form planets. The planets are like big vacuum cleaners, sucking in everything around them. But they didn't complete the job. There's still an awful lot of dust floating around.
When we say that as an astronomer, we can mean anything from objects weighing micrograms, which you wouldn't even see unless you had a microscope, to things that weigh many tons, like comets. All that stuff is still there, being pulled around by the gravity of the planets and the sun. The Earth can't avoid running into this debris, so that dust falls onto the Earth all the time and has from the very beginning. It's why the planet was made in the first place.
Nowadays, you don't even notice it. But eventually all that stuff, which contains oxygen and carbon, iron, nickel, and all the other elements, finds its way into our bodies.
When a really big piece of dust, like a giant comet or asteroid, falls onto the Earth, you get a massive explosion, which is one of the reasons we believe the dinosaurs became extinct some 70 million years ago. That fortunately doesn't happen very often. But things fall out of the sky all the time. [Laughs]
Many everyday commodities we use also began their existence in outer space. Tell us about salt.
Karel: Whatever you mention, its history began in outer space. Take salt. What we usually mean by salt is kitchen salt. It has two chemicals, sodium and chloride. Where did they come from? They were formed inside stars that exploded billions of years ago and at some point found their way onto the Earth. Stellar explosions are still going on today in the galaxy, so some of the chlorine we're eating in salt was made only recently.
You study pathology, Iris. Is physical malfunction part of the cosmic order?
Iris: Absolutely. There are healthy processes, such as growth, for which we need cell division. Then there are processes when things go wrong. We age because we lose the balance between cell deaths and regeneration. That's what we see in the mirror when we age over time. That's also what we see when diseases develop, such as cancers. Cancer is basically a mistake in the DNA, and because of that the whole system can be derailed. Aging and cancer are actually very similar processes. They both originate in the fact that there's a loss of balance between regeneration and cell loss.
Cystic fibrosis is an inherited genetic disease. You inherit an error in the DNA. Because of that, certain tissues do not have the capability to provide their normal function to the body. My work is focused on finding changes in DNA in different populations so we can understand better what kinds of mutations are the basis of that disease. Based on that, we can provide prognosis. There are now drugs that target specific mutations, as well as transplants, so these patients can have a much better life span than was possible 10 or 20 years ago.
How has writing this book changed your view of life—and your view of each other?
Karel: There are two things that struck me, one that I had no idea about. The first is what Iris described earlier—the impermanence of our bodies. As a physicist, I thought the body was built early on, that it would grow and be stable. Iris showed me, over a long series of dinner discussions, that that's not the way it works. Cells die and rebuild all the time. We're literally not what were a few years ago, and not just because of the way we think. Everything around us does this. Nature is not outside us. We are nature.
As far as our relationship is concerned, I always had a great deal of respect for Iris, and physicians in general. They have to know things that I couldn't possibly remember. And that's only grown with time.
Iris: Physics was not my favorite topic in high school. [Laughs] Through Karel and our conversations, I feel that the universe and the world around us has become much more accessible. That was our goal with the book as well. We wanted it to be accessible and understandable for anyone with a high school education. It was a challenge to write it that way, to explain things to each other in lay terms. But it has certainly changed my view of life. It's increased my sense of wonder and appreciation of life.
In terms of Karel's profession and our relationship, it has inevitably deepened. We understand much better what the other person is doing in the sandboxes we respectively play in. [Laughs]
Excerpt from foxnews.com
Astronomers in Australia have picked up an “alien” radio signal from space for the first time as it occurred. The signal, or radio “burst”, was discovered on May 15, 2014, though it’s just being reported by the Monthly Notices of the Royal Astronomical Society. “The burst was identified within 10 seconds of its occurrence,” said Emily Petroff, a doctoral student from Melbourne’s Swinburne University of Technology. “The importance of the discovery was recognized very quickly and we were all working very excitedly to contact other astronomers and telescopes around the world to look at the location of the burst.”
Emerging from an unknown source, these bursts are bright flashes of radio waves that emit as much energy in a few milliseconds as the sun does in 24 hours. “The first fast radio burst was discovered in 2007,” Petroff tells FoxNews.com, “and up until our discovery there were 8 more found in old or archival data.” While researchers use telescopes in Hawaii, India, Germany, Chile, California, and the California Islands to search for bursts, it is the CSIRO Parkes radio telescope in Eastern Australia that is the first to catch one as its happening.
The cause of these mysterious signals remains unknown, with possible theories ranging from black holes to alien communication. However, UFO hunters shouldn’t get too excited. According to Petroff, “We're confident that they're coming from natural sources, that is to say it's probably not aliens, but we haven't solved the case completely. The two most promising theories at the moment are that these bursts could be produced either by a star producing a highly energetic flare, or from a neutron star collapsing to make a black hole. Both of these things would be from sources in far-away galaxies just reaching us from billions of light years away.”
Catching the bursts as they happen is key to finding the source, and though Petroff’s team scrambled upon making their discovery, they didn’t move fast enough to find the afterglow and pin down the cause. “Finding one in real-time has been the goal for a while because we would then be able to act on it and mobilize other telescopes to look that way,” Petroff says. “We did this in the case of this real-time discovery, but we didn't get on the target until about eight hours later with other telescopes, at which time nothing was found.” However, they were able to eliminate a few possible causes, such as gamma-ray bursts from exploding stars and supernovae. Also, the team was able to determine that the source had been near an object with a sizeable magnetic field from the way the wavelengths were polarized.
While the source of the fast radio burst remains a mystery, the team remains hopeful that they can learn from their mistakes and one day solve the case. “All we can do is learn from our experience with this discovery and create a more efficient system for next time,” Petroff says. “We still spend a large amount of time looking for fast radio bursts with the Parkes telescope and the next time we are in the right place at just the right time, we'll be able to act faster than ever before and hopefully solve the mystery once and for all!”
Excerpt from nbcnews.com SpaceX, the California-based rocket company that now has its sights set on a globe-spanning satellite constellation, says it has received a $1 billion investment from Google and Fidelity that values the c...
Excerpt from space.com
Galaxies come in all different shapes and sizes, and a massive new simulation of the universe has captured that galactic variety with more accuracy than any simulation before it, according to a new study.
Using a simulation called EAGLE (Evolution and Assembly of GaLaxies and their Environments), researchers from multiple institutes in Europe have cooked up a dazzling simulation of the universe that contains tens of thousands of galaxies.
A sample of the new simulation can be seen in the video above. It shows the evolution of the universe in a region 25 megaparsecs cubed (about 81 million light years).
"This is really a staggering success, I think it's fair to say," Rob Crain from Liverpool John Moores University and a member of the group that built EAGLE, told Space.com. The researchers are part of a collaboration called the Virgo Consortium for Cosmological Supercomputer Simulations. "Go to our previous generation of simulations, and the galaxies all look like big spherical blobs. Now they form disks and bars and irregular galaxies and different types of ellipticals."
A computer simulation is like a recipe for the universe. Scientists have to start with a list of ingredients and instructions — which actually means a description of the physics that underlie the current universe. While many simulations can recreate the major cosmic ingredients (like stars and galaxies), the subtleties are harder to achieve (like the shape, mass and distribution of those stars and galaxies).
The bottom right corner of the screen shows the time after the Big Bang (denoted by "t"). In the early universe, matter is dispersed and hazy, but gradually coalesces into a sort of web, with long strands of material connecting nodes where galaxies are clustered. At 1:06, the simulation starts again from the beginning and shows the three major components of the model: dark matter (labeled as CDM), gas (the red globs are gas clouds where stars are often born), and stars. The full EAGLE simulation contains an area 100 megaparsecs cubed.
One goal of the EAGLE group was to produce a simulation large enough that it contained all types of galaxies seen in the universe. This allows the researchers to find out if the physics they programmed into EAGLE are accurate for all galaxies, and if they produce the correct number of galaxies in the universe.
Schaye said the picture of the universe created by the EAGLE simulation "is not perfect, but for astronomers the level of agreement is very impressive. It seems we have the main ingredients in place."
Excerpt from cnn.comImagine you're the kind of person who worries about a future when robots become smart enough to threaten the very existence of the human race. For years, you've been dismissed as a crackpot, consigned to the same category of peop...
Excerpt from theweek.com NASA's Kepler finds massive alien planet 180 light years away NASA's Kepler space telescope has discovered its first alien planet since malfunctioning in May 2013,...
Excerpt from
psmag.com
A far cry from the fierce Cold War Space Race between the U.S. and the Soviet Union, exploration in the 21st century is likely to be a much more globally collaborative project.
Today, NASA’s goal to put astronauts on Mars by the 2030s could be a similarly unifying project. And not only in the United States. A far cry from the fierce Cold War Space Race between the U.S. and the Soviet Union, exploration in the 21st century is likely to be a far more globally collaborative project.
Why has the idea of reaching Mars captured the world? A trip to Mars is a priority for many scientific reasons—some believe it’s the planet that most resembles our own, and one that could answer the age-old question of whether we’re alone in the universe—but there’s also been a long popular fascination with the planet, Stofan observed. Ever since Giovanni Virginio Schiaparelli first observed the canali on Mars in the 1800s or when H.G. Wells wrote about aliens from Mars in his 1898 science fiction novel, The War of the Worlds, the planet has loomed large in the public’s imagination.
NASA’s view is to turn over to the private sector those projects that in a sense have become routine so that it can focus its resources on getting to Mars.
This spirit of trans-border ownership and investment seems set to continue. One key part of this is the Global Exploration Roadmap, an effort between space agencies like NASA, France’s Centre National d’Etudes Spatiales, the Canadian Space Agency, and the Japan Aerospace Exploration Agency, among many others, that is intended to aid joint projects from the International Space Station to expeditions to the Moon and near-Earth asteroids—and to reach Mars. On a recent trip to India’s space agency, Stofan recounted to me, she met with many Indian engineers who were just as excited as the Americans to get scientists up there, not only to explore, but also to begin nailing down the question of whether there was ever life on the red planet.It’s also clear that the next stage of space exploration will not only be more global, but will equally involve greater private and public partnerships.
This environment feels a lot different from the secretive and adversarial Space Race days, when the U.S. and Soviet Union battled to reach the moon first. What’s changed? The Cold War is over, of course, but with it, the funding commitment may also be missing this time around. Stofan mentioned, in response to an audience question, that at the time of the Apollo missions, NASA got up to about four percent of the federal budget, while now it’s only around 0.4 percent. The dollars are still large, but perhaps increased international and private cooperation can be seen as an efficient, clever way to do more with less.
So, what does the future hold? NASA is extremely focused on how to get to Mars and back again safely, Stofan told the audience, but the fun role of science fiction, she suggested, is to start envisioning what the steps after that might be. For example, what might it be like to live on Mars? After all, science often gets its inspiration from the creative world. Just look at how similar mobile phones are to the communicators from Star Trek, she pointed out, or the fact that MIT students made a real-life version of the robotic sphere that Luke Skywalker trains with in Star Wars. “Stories are a great counterpoint to science,” she said.
Excerpt from
bloomberg.com
The U.S. is preparing to launch the first craft developed to fly humans to Mars, presaging a second space age -- this one fueled by billionaires like Elon Musk rather than a Cold War contest with the Soviet Union.
An unmanned version of the Orion spaceship built by Lockheed Martin Corp. (LMT) is scheduled for liftoff tomorrow to an altitude of 3,600 miles (5,800 kilometers), the farthest from Earth by a vehicle designed for people since the Apollo program was scrapped in 1972.
Entrepreneurs such as Musk and longtime contractors like Lockheed are helping shape the technology needed to find other homes for humanity in the solar system with an eye to one day commercializing their work.
“These are really exciting times for space exploration and for our nation as we begin to return to the ability to fly humans to space,” said Jim Crocker, vice president and general manager of civil space at Lockheed Martin Space Systems. “What Orion is about is going further into space than humans have ever gone before.”
Speed Limit
After orbiting earth twice, Orion will accelerate to 20,000 miles per hour during descent, mimicking the speeds of a craft returning from a mission to deep space. The capsule is supposed to make a parachute-cushioned splashdown in the Pacific Ocean off Mexico’s Baja peninsula.To explore the universe, the National Aeronautics and Space Administration must first redevelop capabilities abandoned more than 40 years ago when the U.S. shifted focus from Apollo’s lunar forays to rocketing crews a few hundred miles to low Earth orbit.
NASA has used Russian craft to reach the International Space Station since the space shuttle program ended in 2011.
In a strategic shift, the Obama administration canceled plans to return to the moon, turning some flights to commercial companies while setting its sights -- and limited funds -- on pioneering deep space. The Orion capsule was originally commissioned in 2006 for the defunct Constellation program.
Musk, Bezos
Those moves paved the way for technology chieftains including Musk and Amazon.com Inc. (AMZN) founder Jeff Bezos to pursue their own space ambitions.Musk founded Hawthorne, California-based SpaceX in 2002 with the goal of enabling people to live on other planets, a massive endeavor that would require innovations such as reusable rocket stages to lower costs.
Mars is also in focus for NASA as the space agency maps plans to “pioneer the space frontier,” according to a May 29 white paper.
$22 Billion
NASA proposes an initial $22 billion effort that includes two other Orion missions over the next eight years and building a powerful new rocket. The Delta IV being used tomorrow is manufactured by United Launch Alliance, a Lockheed-Boeing Co. (BA) venture.A new Space Launch System rocket being developed by the partnership is slated to hoist the next Orion craft beyond the moon in fiscal 2018, Lockheed’s Crocker said in a phone interview. The first manned Orion mission is slated for early in the next decade.
NASA’s plans are “sketchy” beyond that, aside from broad goals to capture asteroid samples in the 2020s and reach Mars a decade later, said Marco Caceres, director of space studies with Fairfax, Virginia-based consultant Teal Group.
Average Distance
While Mars’s distance from Earth varies because of the two planets’ orbits, the average is about 140 million miles, almost 600 times longer than a trip to the moon. It’s so far that radio communications take as long as 20 minutes to travel each way, according to Bill Hill, NASA’s deputy associate administrator for exploration systems development.Entrepreneurs such as Musk will have opportunities to get involved as NASA refines capsule and rocket designs. NASA plans to develop two larger rockets beyond the initial launch vehicle, which will be capable of hauling a 70-metric ton payload.
“We’re not taking any options off the table,” Hill said. “We want to be sufficiently flexible so that if we find a new path, we can introduce it and not change course.”
Expense, shifting political priorities and the lack of a clear NASA road map could still derail the latest effort as they did the Apollo program in the early 1970s, said Micah Walter-Range, director of research analysis with the Space Foundation, a non-profit organization based in Colorado Springs, Colorado.
“All of the challenges that exist are surmountable,” Walter-Range said by phone. “It’s just a question of having the money to do it.”
Excerpt from huffingtonpost.comIn early December, NASA will take an important step into the future with the first flight test of the Orion spacecraft -- the first vehicle in history capable of taking humans to multiple destinations in deep space. An...
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| Concept model of the FireFly Design (Image credit: Deep Space Industries / Bryan Versteeg. |
Excerpt from geologyforinvestors.com
At first glance it sounds ridiculous. Why would anyone consider mining in space when even the largest Earth-based mining operations seem to have trouble managing costs? After all, mid-grade and marginal deposits seem to have trouble finding any money and the process of moving a project from prospect to mine can take decades and cost hundreds of million of dollars. I’ll be the first to admit that the whole idea of asteroid mining was initially right up there with Star Trek-style transporters and desktop cold fusion, but a few recent events have piqued my curiosity on the subject. Allow me to elaborate.
First, one of the many items that was lost back in October, 2014 when the Antares rocket was destroyed was the Arkyd 3 satellite. Arkyd 3 is a testing platform designed by Planetary Resources, otherwise known as “the asteroid mining company”. Apparently these guys aren’t just doing interviews: There is actual work going on here. A re-built Arkyd 3 is scheduled for launch in about 9 months.
Second, the recent landing of the Philae spacecraft on comet 67P stirred all of our imaginations in a way that was reminiscent of the moon landing, first shuttle launch or first Mars rover. If we can effectively land a bullet on a bullet 500 million miles away from Earth, then the idea of grabbing a near-earth asteroid doesn’t sound nearly as crazy. The economics might still seem crazy, but the technology – not so much.
As it turns out, there are three groups currently working on a long term strategy to gather resources from space. Two are private companies and the third is NASA. All have different approaches, but their end games are largely the same.
What Asteroids? What Resources?
Asteroid miners are seeking out near-earth asteroids. There are over 11,000 known near-earth asteroids which are considered to be left-overs from the formation of the solar system. These bodies can be composed of ice, silicate minerals, carbonaceous minerals and metals.Ice or water on these bodies is one of the most significant potential resources. Solar panels on spacecraft can provide the power to simply convert water to hydrogen and oxygen for fuel. Considering that it costs from $5,000-25,000+ per kg to ferry items into space, the idea of harvesting resources needed in space doesn’t sound like such a bad idea. In fact, the groups involved are primarily focused on gathering the resources needed for space exploration and development. Gathering resources to send back to earth is a much longer term goal and arguably may never be economic.
Groups Involved
Currently there are two private companies pursuing asteroid mining; Planetary Resources and Deep Space Industries. NASA is also involved on several levels and has awarded contracts to several companies including both Planetary Resources and Deep Space Industries for studies relating to relating to asteroid redirection.Deep Space Industries – Fire Fly/DragonFly/Harvestor
Deep Space Industries’ approach includes a series of compact spacecraft known as FireFlies (not to be confused with NASA’s FireFly Cubesat). The company plans to send them on one-way missions to gather information such as size, shape, density and composition of asteroids of interest. Their longer term plan includes the development of a spacecraft known as the “Dragonfly” which will capture asteroids to return for analysis and to test processing methods and the “Harvestors” which will collect material for return to Earth’s orbit. The Harvestor class is meant for full-scale production for initial customers in space from collecting propellant for future space missions, manufacturing materials using extracted metals and radiation shielding. If costs begin to decrease over time they hope to be able to return these extracted commodities back to earth. DSI recently made the news when it partnered with another firm to build Bitcoin satellites as part of a proposed Bitcoin orbital satellite network.NASA
NASA has commissioned a number of studies on the potential for asteroid mining and interactions as part of it’s Early Stage Innovation and Innovative Advanced Concepts (NIAC) directives. The Robotic Asteroid Prospector study determined that water and possibly Platinum Group Metals had the most economic potential for asteroid mining operations and presented some preliminary designed for water extraction.NASA’s OSIRIS REx spacecraft is designed study the the near-Earth “Bennu” asteroid for more than a year with the primary goal of landing on the asteroid and retrieving a sample for return to Earth. OSIRIS-REx is scheduled for launch in September 2016.
NASA has been also been studying robotic mining for several years and holds annual competition where university students can build a mining robot.
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CEO of Tesla Motors is trying to bring the Internet to space
Excerpt from cnet.com The SpaceX CEO wants to build a satellite network high above Earth that would speed up the Internet and bring access to underserved communities. And he'll use the profits to help colonize Mars. Elon Musk, the man who...
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