NASA’s Sci-Fi Vision: Robots Could Help Humanity Mine Asteroids

An artist's conception of a spacecraft designed to pick up an asteroid. Credit: NASA/Advanced Concepts Laboratory

In a few generations of robotics, we’ll see mighty machines able to fully construct themselves and operate from the surface of asteroids — providing applications for mining, NASA researchers say in a new study.

The scientists are convinced that this type of research is not only possible, but also able to support itself financially. (Costs overruns are a notorious factor in space exploration as it pushes frontiers both literally and engineering-wise.)

“Advances in robotics and additive manufacturing have become game-changing for the prospects of space industry. It has become feasible to bootstrap a self-sustaining, self-expanding industry at reasonably low cost,” the researchers stated in a new study.

A couple of factors are pointing to this, researchers said: private industry is willing and able to get involved. Advances in technologies such as 3-D printing are making off-world work more feasible. Also, humanity’s surveys of space resources has revealed the elements needed to make rubber, plastic and alloys needed for machinery.

NASA proposes a robotic flotilla could mine nearby space rocks. They caution the technology won’t be ready tomorrow, and more surveys will need to be done of nearby asteroids to figure out where to go next. There is, however, enough progress to see building blocks, the agency stated.

An artist's conception of a space exploration vehicle approaching an asteroid. Credit: NASA
An artist’s conception of a space exploration vehicle approaching an asteroid. Credit: NASA

“Robots and machines would just make the metal and propellants for starters,” stated Phil Metzger, a senior research physicist at NASA’s Kennedy Space Center, who led the study.

“The first generation of robots makes the second generation of hardware, except the comparatively lightweight electronics and motors that have to be sent up from Earth. It doesn’t matter how much the large structures weigh because you didn’t have to launch it.”

A computer model in the study showed that in six generations of robotics, these machines will be able to construct themselves and operate without any need of materials from Earth.

Artist impression of the Arkyd Interceptor, a low cost asteroid mission that enables accelerated exploration. Credit: Planetary Resources.
Artist impression of the Arkyd Interceptor, a low cost asteroid mission that enables accelerated exploration. Credit: Planetary Resources.

At least two startups would agree with the optimism: Deep Space Industries and Planetary Resources.

In the past year, members of both firms have proposed asteroid mining ideas, and since then, Planetary Resources has also unveiled other projects such as a public space telescope (perhaps in a bid to diversify revenues and attract more attention.)

In early 2013, when NASA submitted its fiscal budget request for 2014, it also got in on the hubbub: the agency proposed robotically venturing out to an asteroid and bringing it back to Earth.

That’s received many questions from critics (including at least one government space committee), but NASA has argued it is feasible and a way to unite innovation across various sectors.

“Because asteroids are loaded with minerals that are rare on Earth, near-Earth asteroids and the asteroid belt could become the mining centers for remotely-operated excavators and processing machinery,” NASA stated.

Asteroid 951 Gaspra
Asteroid 951 Gaspra. Credit: NASA

“In the future, an industry could develop to send refined materials, rare metals and even free, clean energy to Earth from asteroids and other bodies.”

Check out more details of the new report in the Journal of Aerospace Engineering.

A side note, this isn’t the only NASA-funded group looking at asteroid mining. In September, NASA’s Innovative Advanced Concepts office offered Phase 1 funding to a Robotic Asteroid Prospector proposal.

Source: NASA

Curiosity Gets Set for Epic Drive after Laser Blasting Mars Watery Secrets

Curiosity’s hi tech ‘hand’ and percussion drill hovers above 2nd bore hole at Cumberland mudstone rock after penetrating laser blasting to unlock secrets of ancient flow of Martian water. Photo mosaic assembled from high resolution Mastcam images on May 21, 2013, Sol 281. Credit: NASA/JPL-Caltech/MSSS/Ken Kremer (kenkremer.com)/Marco Di Lorenzo

Ten months after her breathtaking touchdown on the Red Planet, NASA’s Curiosity rover is nearly set to embark on an epic drive like no other in space history to the slopes of mysterious Mount Sharp – looming supreme inside Gale Crater and the primary mission objective.

But not before the robot completes a few last critical science tasks to more fully illuminate the potential for the origin of Martian microbes in the habitable zone discovered at the work-site of her first penetrations into Mars water altered surface.

The rover science team has chosen a trio of final targets to investigate around the shallow basin of Yellowknife Bay, that resembles a dried out lakebed, where Curiosity has toiled for the past six months, drilled twice into the mudstone outcrops at ‘John Klein’ and ‘Cumberland’ and repeatedly fired her powerful science laser.

Curiosity will revisit a pair of intriguing outcrops named ‘Point Lake’ and ‘Shaler’ that the rover briefly investigated before arriving at ‘John Klein’, said Joy Crisp of JPL, Curiosity’s deputy project scientist, at a media briefing.

“Shaler might be a river deposit. Point Lake might be volcanic or sedimentary. A closer look at them could give us better understanding of how the rocks we sampled with the drill fit into the history of how the environment changed.”

Curiosity will employ nearly all her science instruments to study the outcrops – except the drill.

“It’s highly unlikely to drill at ‘Point Lake’ and ‘Shaler’ because we want to get driving,” Crisp told Universe Today.

“We might drill somewhere along the way to Mount Sharp depending on whether we find something compelling.”

'Point Lake' Outcrop in Gale Crater.  A priority target for a closer look byCuriosity before the rover departs the "Glenelg" area east of its landing site. The pitted outcrop called "Point Lake" is about 7 feet (2 meters) wide and 20 inches (50 centimeters) high.  A closer inspection may yield information about whether it is a volcanic or sedimentary deposit. Credit: NASA/JPL-Caltech/MSSS
‘Point Lake’ Outcrop in Gale Crater. A priority target for a closer look byCuriosity before the rover departs the “Glenelg” area east of its landing site. The pitted outcrop called “Point Lake” is about 7 feet (2 meters) wide and 20 inches (50 centimeters) high. A closer inspection may yield information about whether it is a volcanic or sedimentary deposit. Credit: NASA/JPL-Caltech/MSSS

Researchers will also use the DAN (Dynamic Albedo of Neutrons) instrument to look for traces of mineral bound water – in the form of hydrogen – at the boundary between bedrock areas of mudstone and sandstone.

Thereafter, Curiosity’s handlers will command the 1 ton behemoth to begin the drive to the lower reaches of Mount Sharp which lies about 6 miles (10 kilometers) distant – as the Martian crow flies.

Mount Sharp rises about 3.4 miles (5.5 km) from the center of Gale Crater. It’s taller than Mount Ranier in Washington State.

Billions of years of Mars geologic history are preserved in the sedimentary layers of Mount Sharp – along with potential signatures of the chemical ingredients of life.

Curiosity Route Map From 'Glenelg' to Mount Sharp. This map shows where NASA's Mars rover Curiosity landed in August 2012 at "Bradbury Landing"; the area where the rover worked from November 2012 through May 2013 at and near the "John Klein" target rock in the "Glenelg" area; and the mission's next major destination, the entry point to the base of Mount Sharp.  Credit: NASA/JPL-Caltech/Univ. of Arizona
Curiosity Route Map From ‘Glenelg’ to Mount Sharp.
This map shows where NASA’s Mars rover Curiosity landed in August 2012 at “Bradbury Landing”; the area where the rover worked from November 2012 through May 2013 at and near the “John Klein” target rock in the “Glenelg” area; and the mission’s next major destination, the entry point to the base of Mount Sharp. Credit: NASA/JPL-Caltech/Univ. of Arizona

“The drive will start in a few weeks,” said Curiosity Project Manager Jim Erickson of NASA’s Jet Propulsion Laboratory, Pasadena, Calif. at the briefing.

But the team will be on the lookout for targets of opportunity along the way.

“We are on a mission of exploration. If we come across scientifically interesting areas, we are going to stop and examine them before continuing the journey,” Erikson added.

“If we pass something amazing and compelling we might turn around and drive back,” Crisp added.

It could take nearly a year to arrive at Mount Sharp. And Curiosity must pass through a potentially treacherous dune field to get there – see NASA JPL route map above.

“We are looking for the best path though,” said Erickson.

NASA chose Gale as the landing site specifically to dispatch Curiosity to investigate the sedimentary layers of Mount Sharp because it exhibited signatures of clay minerals that form in neutral water and that could possibly support the origin and evolution of simple Martian life forms, past or present.

“We have a real desire to get to Mount Sharp because there we see variations in the mineralogy as we go up from the base to higher levels and a change in the record of the environment,” said Crisp.

Analysis of the initial gray colored, powdery ‘John Klein’ sample by Curiosity’s pair of onboard chemistry labs – SAM & Chemin – revealed that this location on Mars was habitable in the past and possesses the key chemical ingredients – such as clay minerals – required to support microbial life forms- thereby successfully accomplishing the key science objective of the mission and making a historic discovery long before even arriving at destination Mount Sharp.

Besides the science measurements, researchers also learned lot about how to operate the complex drilling and sample delivery mechanisms much more efficiently for the second drilled rock sample.

The sieved and pulverized Cumberland sample was delivered in about a quarter of the time compared to the John Klein sample – accomplished at a deliberately measured and cautious pace.

Context view of Curiosity’s 2nd drill site at Cumberland rock on the floor of Yellowknife Bay basin of ancient water altered rocks where the rover found environmental conditions favorable for microbial life. Mastcam images on May 23, 2013, Sol 283.  Credit: NASA/JPL-Caltech/MSSS/Ken Kremer (kenkremer.com)/Marco Di Lorenzo
Context view of Curiosity’s 2nd drill site at Cumberland rock on the floor of Yellowknife Bay basin showing ancient water altered rocks where the rover found environmental conditions favorable for microbial life. Mastcam images on May 23, 2013, Sol 283. Credit: NASA/JPL-Caltech/MSSS/Ken Kremer (kenkremer.com)/Marco Di Lorenzo

Analysis of the “Cumberland” powder is currently in progress. The goal is to determine how it compares chemically and to confirm the results found at ‘John Klein.’

“No results from Cumberland are available yet,” said Crisp.

The robot used the powerful million watt ChemCam laser to blast into the Cumberland drill hole and gray tailings scattered on the surface to glean as much insight and measurements of the chemical composition and transformation by water as possible before departing.

Curiosity has just arrived at “Point Lake’. Stay tuned for my next Curiosity story.

Meanwhile, Curiosity’s older sister rover Opportunity has likewise discovered clay minerals and a habitable zone on the opposite side of the Red Planetdetails here.

And don’t forget to “Send Your Name to Mars” aboard NASA’s MAVEN orbiter- details here. Deadline: July 1, 2013

Ken Kremer

…………….

Learn more about Mars, Curiosity, Opportunity, MAVEN, LADEE and NASA missions at Ken’s upcoming lecture presentations

June 23: “Send your Name to Mars on MAVEN” and “CIBER Astro Sat, LADEE Lunar & Antares Rocket Launches from Virginia”; Rodeway Inn, Chincoteague, VA, 8 PM

This time lapse mosaic shows Curiosity moving her robotic arm to drill into her 2nd rockt target named “Cumberland” to collect powdery material on May 19, 2013 (Sol 279) for analysis by her onboard chemistry labs; SAM & Chemin. The photomosaic was stitched from raw images captured by the navcam cameras on May 14 & May 19 (Sols 274 & 279).  Credit: NASA/JPL-Caltech/Ken Kremer/Marco Di Lorenzo
This time lapse mosaic shows Curiosity moving her robotic arm to drill into her 2nd rockt target named “Cumberland” to collect powdery material on May 19, 2013 (Sol 279) for analysis by her onboard chemistry labs; SAM & Chemin. The photomosaic was stitched from raw images captured by the navcam cameras on May 14 & May 19 (Sols 274 & 279). Credit: NASA/JPL-Caltech/Ken Kremer/Marco Di Lorenzo

Closest Star to the Sun

What is the Closest Star?
What is the Closest Star?

This is a classic trick question. Ask a friend, “what is the closest star?” and then watch as they try to recall some nearby stars. Sirius maybe? Alpha something or other? Betelgeuse?

The answer, obviously, is the Sun; that massive ball of plasma located a mere 150 million km from Earth.

Let’s be more precise; what’s the closest star to the Sun?

Closest Star

You might have heard that it’s Alpha Centauri, the third brightest star in the sky, just 4.37 light-years from Earth.

But Alpha Centauri isn’t one star, it’s a system of three stars. First, there’s a binary pair, orbiting a common center of gravity every 80 years. Alpha Centauri A is just a little more massive and brighter than the Sun, and Alpha Centauri B is slightly less massive than the Sun. Then there’s a third member of this system, the faint red dwarf star, Proxima Centauri.

It’s the closest star to our Sun, located just a short 4.24 light-years away.

Closest Star, Proxima Centauri
Proxima Centauri

Alpha Centauri is located in the Centaurus constellation, which is only visible in the Southern Hemisphere. Unfortunately, even if you can see the system, you can’t see Proxima Centauri. It’s so dim, you need a need a reasonably powerful telescope to resolve it.

Let’s get sense of scale for just how far away Proxima Centauri really is. Think about the distance from the Earth to Pluto. NASA’s New Horizons spacecraft travels at nearly 60,000 km/h, the fastest a spacecraft has ever traveled in the Solar System. It will have taken more than nine years to make this journey when it arrives in 2015. Travelling at this speed, to get to Proxima Centauri, it would take New Horizons 78,000 years.

Proxima Centauri has been the nearest star for about 32,000 years, and it will hold this record for another 33,000 years. It will make its closest approach to the Sun in about 26,700 years, getting to within 3.11 light-years of Earth. After 33,000 years from now, the nearest star will be Ross 248.

What About the Northern Hemisphere?

Bernard's Star, one of the closest stars to the Sun
Bernard’s Star
For those of us in the Northern Hemisphere, the closest visible star is Barnard’s Star, another red dwarf in the constellation Ophiuchus. Unfortunately, just like Proxima Centauri, it’s too dim to see with the unaided eye.

The closest star that you can see with the naked eye in the Northern Hemisphere is Sirius, the Dog Star. Sirius, has twice the mass and is almost twice the size of the Sun, and it’s the brightest star in the sky. Located 8.6 light-years away in the constellation Canis Major – it’s very familiar as the bright star chasing Orion across the night sky in Winter.

How do Astronomers Measure the Distance to Stars?

They use a technique called parallax. Do a little experiment here. Hold one of your arms out at length and put your thumb up so that it’s beside some distant reference object. Now take turns opening and closing each eye. Notice how your thumb seems to jump back and forth as you switch eyes? That’s the parallax method.

To measure the distance to stars, you measure the angle to a star when the Earth is one side of its orbit; say in the summer. Then you wait 6 month, until the Earth has moved to the opposite side of its orbit, and then measure the angle to the star compared to some distant reference object. If the star is close, the angle will be measurable, and the distance can be calculated.

You can only really measure the distance to the nearest stars this way, since it only works to about 100 light-years.

The 20 Closest Stars

Here is a list of the 20 closest star systems and their distance in light-years. Some of these have multiple stars, but they’re part of the same system.

  1. Alpha Centauri – 4.2
  2. Barnard’s Star – 5.9
  3. Wolf 359 – 7.8
  4. Lalande 21185 – 8.3
  5. Sirius – 8.6
  6. Luyten 726-8 – 8.7
  7. Ross 154 – 9.7
  8. Ross 248 – 10.3
  9. Epsilon Eridani – 10.5
  10. Lacaille 9352 – 10.7
  11. Ross 128 – 10.9
  12. EZ Aquarii – 11.3
  13. Procyon – 11.4
  14. 61 Cygni – 11.4
  15. Struve 2398 – 11.5
  16. Groombridge 34 – 11.6
  17. Epison Indi – 11.8
  18. Dx Carncri – 11.8
  19. Tau Ceti – 11.9
  20. GJ 106 – 11.9

According to NASA data, there are 45 stars within 17 light years of the Sun. There are thought to be as many as 200 billion stars in our galaxy. Some are so faint that they are nearly impossible to detect. Maybe, with technological improvements, scientists will find even closer stars.

Navy Researchers Put Dark Lightning to the SWORD

Dark lightning occurs within thunderstorms and flings gamma rays and antimatter into space. (Science@NASA video)

Discovered “by accident” by NASA’s Fermi Gamma-ray Space Telescope in 2010, dark lightning is a surprisingly powerful — yet invisible — by-product of thunderstorms in Earth’s atmosphere. Like regular lightning, dark lightning is the result of a natural process of charged particles within storm clouds trying to cancel out opposing charges. Unlike normal lightning, though, dark lightning is invisible to our eyes and doesn’t radiate heat or light — instead, it releases bursts of gamma radiation.

What’s more, these gamma-ray outbursts originate at relatively low altitudes well within the storm clouds themselves. This means that airplane pilots and passengers flying through thunderstorms may be getting exposed to gamma rays from dark lightning, which are energetic enough to pass through the hull of an aircraft… as well as anything or anyone inside it. To find out how such exposure to dark lightning could affect air travelers, the U.S. Naval Research Laboratory (NRL) is conducting computer modeling tests using their SoftWare for the Optimization of Radiation Detectors — SWORD, for short.

Terrestrial Gamma-ray Flashes (TGFs) are extremely intense, sub-millisecond bursts of gamma rays and particle beams of matter and anti-matter. First identified in 1994, they are associated with strong thunderstorms and lightning, although scientists do not fully understand the details of the relationship to lightning. The latest theoretical models of TGFs suggest that the particle accelerator that creates the gamma rays is located deep within the atmosphere, at altitudes between six and ten miles, inside thunderclouds and within reach of civilian and military aircraft.

These models also suggest that the particle beams are intense enough to distort and collapse the electric field within thunderstorms and may, therefore, play an important role in regulating the production of visible lightning. Unlike visible lightning, TGF beams are sufficiently broad — perhaps about half a mile wide at the top of the thunderstorm — that they do not create a hot plasma channel and optical flash; hence the name, “dark lightning.”

A team of NRL Space Science Division researchers, led by Dr. J. Eric Grove of the High Energy Space Environment (HESE) Branch, is studying the radiation environment in the vicinity of thunderstorms and dark lightning flashes. Using the Calorimeter built by NRL on NASA’s Fermi Gamma-ray Space Telescope they are measuring the energy content of dark lightning and, for the first time, using gamma rays to geolocate the flashes.

As a next step, Dr. Chul Gwon of the HESE Branch is using NRL’s SoftWare for the Optimization of Radiation Detectors (SWORD) to create the first-ever simulations of a dark lightning flash striking a Boeing 737. He can calculate the radiation dosage to the passengers and crew from these Monte Carlo simulations. Previous estimates have indicated it could be as high as the equivalent of hundreds of chest X-rays, depending on the intensity of the flash and the distance to the source.

Simulation of a Boeing 737 struck by dark lightning. Green tracks show the paths of gamma rays from the dark flash as they enter the aircraft from below.   (Credit: U.S. Naval Research Laboratory)
Simulation of a Boeing 737 struck by dark lightning. Green tracks show the paths of gamma rays from the dark flash as they enter the aircraft from below.
(Credit: U.S. Naval Research Laboratory)

SWORD simulations allow researchers to study in detail the effects of variation in intensity, spectrum, and geometry of the flash. Dr. Grover’s team is now assembling detectors that will be flown on balloons and specialized aircraft into thunderstorms to measure the gamma ray flux in situ. The first balloon flights are scheduled to take place this summer.

Source: NRL News

Should This Alien World Even Exist? This Young Disk Could Challenge Planet-Formation Theories

An image of TW Hydrae and the protoplanetary stuff surrounding the star. Astronomers believe a planet is forming within the gas and dust and sweeping up debris, as shown by the gap in this picture. Credit: NASA, ESA, J. Debes (STScI), H. Jang-Condell (University of Wyoming), A. Weinberger (Carnegie Institution of Washington), A. Roberge (Goddard Space Flight Center), and G. Schneider (University of Arizona/Steward Observatory)

Take a close look at the blurry image above. See that gap in the cloud? That could be a planet being born some 176 light-years away from Earth. It’s a small planet, only 6 to 28 times Earth’s mass.

That’s not even the best part.

This alien world, if we can confirm it, shouldn’t be there according to conventional planet-forming theory.

The gap in the image above — taken by the Hubble Space Telescope — probably arose when a planet under construction swept through the dust and debris in its orbit, astronomers said.

That’s not much of a surprise (at first blush) given what we think we know about planet formation. You start with a cloud of debris and gas swirling around a star, then gradually the bits and pieces start colliding, sticking together and growing bigger into small rocks, bigger ones and eventually, planets or gas giant planet cores.

But there’s something puzzling astronomers this time around: this planet is a heck of a long way from its star, TW Hydrae, about twice Pluto’s distance from the sun. Given that alien systems’ age, that world shouldn’t have formed so quickly.

An illustration of TW Hydrae's disk in comparison with that of Earth's solar system. Credit: NASA, ESA, and A. Feild (STScI)
An illustration of TW Hydrae’s disk in comparison with that of Earth’s solar system. Credit: NASA, ESA, and A. Feild (STScI)

Astronomers believe that Jupiter took about 10 million years to form at its distance away from the sun. This planet near TW Hydrae should take 200 times longer to form because the alien world is moving slower, and has less debris to pick up.

But something must be off, because TW Hydrae‘s system is believed to be only 8 million years old.

“There has not been enough time for a planet to grow through the slow accumulation of smaller debris. Complicating the story further is that TW Hydrae is only 55 percent as massive as our sun,” NASA stated, adding it’s the first time we’ve seen a gap so far away from a low-mass star.

The lead researcher put it even more bluntly: “Typically, you need pebbles before you can have a planet. So, if there is a planet and there is no dust larger than a grain of sand farther out, that would be a huge challenge to traditional planet formation models,” stated John Debes, an astronomer at the Space Telescope Science Institute in Baltimore.

Protoplanet Hypothesis
Like a raindrop forming in a cloud, a star forms in a diffuse gas cloud in deep space. As the star grows, its gravitational pull draws in dust and gas from the surrounding molecular cloud to form a swirling disk called a “protoplanetary disk.” This disk eventually further consolidates to form planets, moons, asteroids and comets. Credit: NASA/JPL-Caltech

At this point, you would suppose the astronomers are seriously investigating other theories. One alternative brought up in the press release: perhaps part of the disc collapsed due to gravitational instability. If that is the case, a planet could come to be in only a few thousand years, instead of several million.

“If we can actually confirm that there’s a planet there, we can connect its characteristics to measurements of the gap properties,” Debes stated. “That might add to planet formation theories as to how you can actually form a planet very far out.”

A rare double transit of Jupiter's moon Ganymede (top) and Io on Jan. 3, 2013. Here, the sun is shining from the left causing shadows cast by the moons to fall onto the planet's cloud tops. Credit: Damian Peach
A rare double transit of Jupiter’s moon Ganymede (top) and Io on Jan. 3, 2013. Here, the sun is shining from the left causing shadows cast by the moons to fall onto the planet’s cloud tops. Credit: Damian Peach

There’s a trick with the “direct collapse” theory, though: astronomers believe it takes a bunch of matter that is one to two times more massive than Jupiter before a collapse can occur to form a planet.

Recall that this world is no more than 28 times the mass of Earth, as best as we can figure. Well, Jupiter itself is 318 times more massive than Earth.

There are also intriguing results about the gap. Chile’s Atacama Large Millimeter/submillimeter Array (ALMA) — which is designed to look at dusty regions around young stars — found that the dust grains in this system, orbiting nearby the gap, are still smaller than the size of a grain of sand.

Astronomers plan to use ALMA and the James Webb Space Telescope, which should launch in 2018, to get a better look. In the meantime, the results will be published in the June 14 edition of the Astrophysical Journal.

Source: HubbleSite

The Epitome of Cool: Neil Armstrong and David Scott, 1966

Neil Armstrong and David Scott in the Gemini VIII capsule, after splashdown, March 16, 1966. Credit: NASA.

So, you’ve just endured a harrowing experience where your orbiting spacecraft has gone wildly out of control. You somehow — while undergoing the incredible, vertigo-inducing G-forces of your spinning spacecraft — figure out a plan, undock your spacecraft from another spacecraft and abort your original mission.

Six and a half orbits and ten hours and 44 minutes after you’ve thunderously launched into space, you violently re-enter Earth’s atmosphere and splash down in a pitching ocean. Obviously, you have to throw up, and so does your crewmate. But there’s just one air sickness bag.

But by the time the rescue crew has arrived you’ve donned your sunglasses and look as cool as a cucumber.

That’s Neil Armstrong and Dave Scott’s experience during the Gemini 8 mission.

The epitome of cool.

MESSENGER’s Unique View: A Colorful, Spinning Planet Mercury

The different colors in this MESSENGER image of Mercury indicate the chemical, mineralogical, and physical differences between the rocks that make up the planet’s surface. Credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington.

The MESSENGER mission has now mapped the entire surface of planet Mercury — and this is the first time this has even been done. MESSENGER is the first spacecraft to be in orbit of Mercury, and has been there since 2011, with a couple of flybys starting in 2008 as it slowly looped its way into orbit. The seven scientific instruments and radio science investigation on the spacecraft have provided an entirely new view of the planet.

This colorful view of Mercury is, of course, not what Mercury would look like to the human eye. It was created by using images from the color base map imaging campaign during MESSENGER’s primary mission. These colors enhance the chemical, mineralogical, and physical differences between the rocks that make up Mercury’s surface, allowing scientists to figure out all the different minerals that are on the planet’s surface.

The complete map of Mercury was completed and released in February of 2013, and is made of thousands of images taken by MESSENGER. The spinning video map shows Mercury as, really, we’ve not seen it before, and it is fun to watch features like large rayed craters and basins spin into view.

The MESSENGER team explained the colors:

Young crater rays, extending radially from fresh impact craters, appear light blue or white. Medium- and dark-blue areas are a geologic unit of Mercury’s crust known as the “low-reflectance material”, thought to be rich in a dark, opaque mineral. Tan areas are plains formed by eruption of highly fluid lavas. The giant Caloris basin is the large circular tan feature located just to the upper right of center of the image.

You can see an image of the other side of Mercury here, and the complete gallery of science images and mosaics here.

Where Is Dark Matter Most Dense? Subaru Telescope Gets Some Hints

The Subaru Telescope. Credit: National Astronomical Observatory of Japan

Put another checkmark beside the “cold dark matter” theory. New observations by Japan’s Subaru Telescope are helping astronomers get a grip on the density of dark matter, this mysterious substance that pervades the universe.

We can’t see dark matter, which makes up an estimated 85 percent of the universe, but scientists can certainly measure its gravitational effects on galaxies, stars and other celestial residents. Particle physicists also are on the hunt for a “dark matter” particle — with some interesting results released a few weeks ago.

The latest experiment with Subaru measured 50 clusters of galaxies and found that the density of dark matter is largest in the center of these clusters, and smallest on the outskirts. These measurements are a close match to what is predicted by cold dark matter theory, scientists said.

Cold dark matter assumes that this material can’t be observed in any part of the electromagnetic spectrum, the band of light waves that ranges from high-energy X-rays to low-energy infrared heat. Also, the theory dictates that dark matter is made up of slow-moving particles that, because they collide with each other infrequently, are cold. So, the only way dark matter interacts with other particles is by gravity, scientists have said.

To check this out, Subaru peered at “gravitational lensing” in the sky — areas where the light of background objects are bent around dense, massive objects in front. Galaxy clusters are a prime example of these super-dense areas.

Several dark matter maps: one based on a sample of 50 individual galaxy clusters (left), another looking at an average galaxy cluster (center), and another based on dark matter theory (right). Red is the highest concentration of dark matter, followed by yellow, green and blue. At right, in the middle, is a map based on cold dark matter theory that comes close to the average galaxy cluster observed with the Suburu Telescope. Credit: NAOJ/ASIAA/School of Physics and Astronomy, University of Birmingham/Kavli IPMU/Astronomical Institute, Tohoku University)
Several dark matter maps: one based on a sample of 50 individual galaxy clusters (left), another looking at an average galaxy cluster (center), and another based on dark matter theory (right). Red is the highest concentration of dark matter, followed by yellow, green and blue. At right, in the middle, is a map based on cold dark matter theory that comes close to the average galaxy cluster observed with the Suburu Telescope. Credit: NAOJ/ASIAA/School of Physics and Astronomy, University of Birmingham/Kavli IPMU/Astronomical Institute, Tohoku University)

“The Subaru Telescope is a fantastic instrument for gravitational lensing measurements. It allows us to measure very precisely how the dark matter in galaxy clusters distorts light from distant galaxies and gauge tiny changes in the appearance of a huge number of faint galaxies,” stated Nobuhiro Okabe, an astronomer at Academia Sinica in Taiwan who led the study.

Next, the team members could compare where the matter was most dense with that predicted by cold dark matter theory. To do that, they measured 50 of the most massive, known clusters of galaxies. Then, they measured the “concentration parameter”, or the cluster’s average density.

 

“They found that the density of dark matter increases from the edges to the center of the cluster, and that the concentration parameter of galaxy clusters in the near universe aligns with CDM theory,” stated the National Astronomical Observatory of Japan.

The next step, researchers stated, is to measure dark matter density in the center of the galaxy clusters. This could reveal more about how this substance behaves. Check out more about this study in Astrophysical Journal Letters.

Sourcs: National Astronomical Observatory of Japan

Bringing Space to the Masses: Q&A with Planetary Resources’ Chris Lewicki

Chris Lewicki in the clean room. His role as flight director for the two MER rovers and surface operations manager for the Phoenix mission required an intimate knowledge of all the spacecraft systems. Image courtesy Chris Lewicki.

Chris Lewicki is the President and Chief Engineer for one of the most pioneering and audacious companies in the world today. Planetary Resources was founded in 2008 by two leading space advocates, Peter Diamandis, Chairman and CEO of the X-Prize Foundation and Eric Anderson, a forerunner in the field of space tourism. In from the earliest days of the company, in turning to Lewicki, Anderson and Diamandis have gained scientific and management expertise which reaches far beyond low Earth orbit.

Chris is a recipient of two NASA Exceptional Achievement Medals and has an asteroid name in his honour, 13609 Lewicki. Chris holds bachelor’s and master’s degrees in Aerospace Engineering from the University of Arizona.

In this exclusive interview with Nick Howes, Lewicki gives us a feel for what lies behind Planetary Resources most compelling step yet in their quest to bring space to the masses.

Chris Lewicki is the President and Chief Engineer for Planetary Resources, Inc. Image courtesy Planetary Resources.
Chris Lewicki is the President and Chief Engineer for Planetary Resources, Inc. Image courtesy Planetary Resources.

Nick Howes – So Chris, what first inspired you to get in to astronomy and space science?

Chris Lewicki – So, I guess it wasn’t a person as most would say, but a mission that got me started on this road. Even before college, and you have to remember I grew up in dairy country in Northern Wisconsin, where we didn’t really have much in the way of space. I wanted to do something interesting, and found I was good at math. When I saw the Voyager 2 spacecraft flyby of Neptune and Triton, I thought “wow this is it,” and wanted to work at JPL pretty much from that moment onwards. Thinking that this was a “really special place.”

Voyager 2's encounter with Nepture. Credit: NASA
Voyager 2’s encounter with Nepture. Credit: NASA

NH – At college were you determined to work for someone like NASA, and was your time at Blastoff a good stepping stone in to this?

CL – I think it really did start even before college, like I said, from the Voyager 2 encounter and all the subsequent missions which JPL were involved in this was kind of the goal. Ahead of JPL though, was my first encounter with Peter (Diamandis) and Eric (Anderson) when we worked on starport.com where I was a web developer. Prior to that I’d had a spell at the Goddard Space Flight Centre, but with Eric and Peter, we really did form a bond. Starport didn’t last too long though, as it was at the time of the dotcom boom and bubble, but it taught me some valuable lessons in those months.

Then I took up a position at JPL, but as you probably know, not everything they do is mission design and planning, and while it is an amazing place, I wanted to get my hands on some real mission stuff, so moved on after just under a year.

Then came Blastoff which kind of set a lot of the wheels in motion for ideas relating to the Google Lunar X-Prize. We had a lot of fun there designing rovers and exploratory missions to the Moon, lots of great people with great ideas.

I was then at a small satellites conference in Utah, when a representative of JPL came up to me after my talk, gave me his business card and effectively said I should come and do an interview for them. Peter and Eric didn’t really want me to go, but I told them “I really have to go off and learn how to build rockets.” Thus really started the real journey working with NASA on some of the most exciting missions in recent history.

NH – How thrilling was it being the flight director for two of the most successful missions in NASA’s history?

A view of the Flight Control room at the Jet Propulsion Laboratory during the landing of the Spirit Mars Exploration Rover, Spirit, with Chris in the  Flight Director hotseat. Credit: NASA/JPL.
A view of the Flight Control room at the Jet Propulsion Laboratory during the landing of the Spirit Mars Exploration Rover, Spirit, with Chris in the Flight Director hotseat. Credit: NASA/JPL.

CL – Thrilling really doesn’t come close to covering it. There I was, 29 years old, thinking “should I really be doing this?” but then, realising “yes, I can do this” sitting in the flight directors desk for two of NASA’s most audacious missions, being Spirit and Opportunity. It was my role to get them safely down on the surface, and boy did we test those missions.

The simulators were so realistic; we’d be running so many different scenarios for years prior to the actual EDL phase, now known as the “7 minutes of terror”. It really doesn’t feel quite real though when it’s actually happening, you just know it is because the room is full of TV cameras, and you have that extra notion in the back of your mind saying it’s not a sim this time. The telemetry though in the simulations was so close to the real data, just a few variations, it kind of showed how much testing and planning went in to those missions, and how it all paid off.

NH – With Phoenix you’d obviously experienced the sadness of the loss of Polar Lander before hand; did that teach you any valuable lessons which you have now carried forward to your role at Planetary Resources?

CL – Phoenix started with a failure review, but that’s what I think is so important about engineering and indeed life in general. You have to fail to understand how to make things better. During that design review we figured out a dozen more reasons for things that could have gone wrong with Mars Polar Lander, and implemented the changes for Phoenix. You have to plan for failure so much with missions of this type, and it’s quite an exhilarating but in some ways stressful ride, and one that after Phoenix I felt like I needed to pass the mantle on to for Curiosity.

NH – On the topic of Planetary Resources, when did you start to think about being part of a company of this magnitude?

Artist concept of the ARKYD spacecraft by an asteroid. Credit: Planetary Resources.
Artist concept of the ARKYD spacecraft by an asteroid. Credit: Planetary Resources.

CL – Well working with Peter and Eric again was mooted as long ago as 2008, the company ideas being formulated then when it was called Arkyd Astronautics, a name which stuck with us until 2012. Eric and Peter approached me about possibly coming back. As I said, I’d pretty much resigned myself to not working on Curiosity, and having to put myself through all of the phases associated with that landing, and there’s a quote which many people believe comes from Mark Twain, but is really from Jackson Brown, that basically says

“Twenty years from now you will be more disappointed by the things that you didn’t do than by the ones you did do. So throw off the bowlines. Sail away from the safe harbor. Catch the trade winds in your sails. Explore. Dream. Discover” I decided to throw off the bowlines and set sail with Planetary Resources.

NH – How do you see your relationship with a company like Planetary Resources with the major space agencies? Do you see yourselves as complimenting them or competing?

CL – Complimenting totally. NASA has over 50 years of incredible exploration, missions, research, development and insight, and a great future ahead of them too. With NASA recently transferring some of their low Earth orbit operations in to the commercial sector, we feel that this is really a great time to be in this industry, with our goals for being at the forefront of the types of science and commercial operations that the business sector can excel in, leaving NASA to focus on the amazing deep space missions, like landing on Europa or going back to Titan, missions like that, which only the large government agencies can really pull off at this time.

NH – The Arkyd has to be one of the most staggering Kickstarter success stories ever, raising aaround $800,000 in a week…did you imagine that the reaction to putting a space telescope available for all in to orbit would garner so much enthusiasm?

Artist concept of the ARKYD telescope in space. Credit: Planetary Resources.
Artist concept of the ARKYD telescope in space. Credit: Planetary Resources.

CL – Staggering again doesn’t really do it enough justice. This is the biggest space based Kickstarter in their history, as it’s also in the photography category; it’s the biggest photographic Kickstarter ever too. We have many more surprises planned which I can’t go in to now, but in setting the $1 million minimum bar to “test the water” with public interest in a space telescope, we’ve not really exceeded expectations, but absolutely reached what we felt was possible. From talking to people ahead of the launch, and just seeing their reaction (note from author, I was one of those people, and my reaction was jaw dropping) we knew we had something really special. The idea of the space selfie we felt was part of the cornerstone of what we wanted to achieve, opening up space to everyone, not just the real die hard space enthusiasts.

NH – With the huge initial success of the Arkyd project, do you see any scope for a flotilla of space telescopes for the public, much like say the LCOGT or iTelescope networks are on Earth?

CL – Possibly in the future. You yourself know with your work with the Las Cumbres and Faulkes network and iTelescope networks that having a suite of telescopes around the planet has huge benefits when it comes to observations and science. At present we have the plan for one telescope for public use as you know.

The Arkyd 100, which will be utilising our Arkyd technologies, which we’ll be using to examine near Earth asteroids. If you think, that in the last 100 years, the Hale’s, Lowell’s etc of this world were all private individuals sponsoring and building amazing instruments for space exploration, it’s really just a natural progression on from this. We’re partnering closely with the Planetary Society on this, as they have common goals and interests to us, and also with National Geographic. We feel this really does open up space to a whole new group of people, and it’s apparent from the phenomenal interest we’ve had from Kickstarter, and the thousands of people who’ve pledged their support, that this vision was right.

NH – Planetary Resources has some huge goals in terms of asteroids in future, but you seem to have a very balanced and phased scientific plan to study and then proceed to the larger scale operations. Does this come from your science background?

CL – As I said, I grew up in dairy country in Wisconsin, where I had to really make my own opportunities be a part of this industry, there was no space there. On saying that, I have been an advocate of space pretty much all my life, and yes, I guess my scientific background, and experience with working at JPL has come to bear in Planetary Resources. We have a solid plan in terms of risk management with our “swarm” mentality, of sending up lots of spacecraft, and even if one or more fails, we’ll still be able to get valuable science data. I see it really in that lots of people have big ideas, and set up companies with them, but then after initial investment dries up, the ideas may still be big and there, but there is no way to pursue them.

We’ve all come from companies which have seen this kind of mindset in the past, and now, whilst we love employing students and college graduates who have big ideas, who take chances, we have a plan, a long term, and sustainable plan, and yes, we’re taking a steady approach to this, so that we can guarantee that our investors get a return on what they have supported.

NH – Can you give us a timeline for what Planetary Resources aim to achieve?

CL – Our first test launch will be as early as 2014, and then in 2015 we’ll start with the space telescopes using the Arkyd technology. By 2017 we hope to be identifying and on our way to classification of potentially interesting NEO targets for future mining. By the early 2020’s the aim is to be doing extraction from asteroids, and starting sample return missions.

NH – You were and still it seems from all I have read, remain passionate about student involvement, with SEDS etc, what could you say to younger people inspired by what you’re doing to encourage them to get in to the space industry?

CL – Tough one, but I’d say that looking at the people you admire, always remember that they are not superhuman, they are like you and me, but to have goals, take chances and be determined is a great way to look forward. The SEDS movement played a big part in my early life, and I would encourage any student to get involved in that for sure.

NH – In conclusion, what would be your ultimate goal as a pioneer of the new frontier in space exploration?

CL – Our ultimate goal is to be the developer of the economic engine that makes space exploration commercially viable. Once we have established that, we can then look at more detailed exploration of space, with tourism, scientific missions, and extending our reach out even further. I’ve already been a part of placing three missions on the surface of Mars, so nothing really is beyond our reach.

Nick’s closing comments :

I first met Chris at the Spacefest V conference in Tucson, where he gave me a preview of the Arkyd space telescope. There is no doubt in my mind that after meeting him, that he and the team at Planetary Resources will succeed in their mission. A quite brilliant individual, but humble with it, someone who you can spend hours talking to and come away feeling truly inspired. This interview we talked for what seemed like hours, and Chris said I could have written a book with the answers he gave, I hope this article gives you some taste however of the person behind the missions which, at the new frontier of exploration, much like the prospectors in the Gold Rush, are charting new and unknown, yet hugely exiting territories. As the old saying goes…and possibly more aptly then ever… watch this space.

You can find out more about the ARKYD project at the Planetary Resources website.

New Video Map Shows Large-Scale Cosmic Structure out to 300 million Light Years

Map showing all galaxies in the local universe color-coded by their distance to us: blue galaxies are the closest, and red are farther, up to 300 million light-years away. Credit: University of Hawaii.

Researchers with the Cosmic Flows project have been working to map both visible and dark matter densities around our Milky Way galaxy up to a distance of 300 million light-years, and they’ve now released this new video map which shows the motions of structures of the nearby Universe in greater detail than ever before.

“The complexity of what we are seeing is almost overwhelming,” says researcher Hélène Courtois, associate professor at the University of Lyon, France, and associate researcher at the Institute for Astronomy (IfA), University of Hawaii (UH) at Manoa. Courtois narrates the video.

The video zooms into our local area of the Universe — our Milky Way galaxy lies in a supercluster of 100,000 galaxies — and then slowly draws back to show the cosmography of the Universe out to 300 million light years.

The map shows how the large-scale structure of the Universe is a complex web of clusters, filaments, and voids. Large voids are bounded by filaments that form superclusters of galaxies. These are the largest structures in the universe.

The team explains:

The movements of the galaxies reveal information about the main constituents of the Universe: dark energy and dark matter. Dark matter is unseen matter whose presence can be deduced only by its effect on the motions of galaxies and stars because it does not give off or reflect light. Dark energy is the mysterious force that is causing the expansion of the universe to accelerate.

Read more about this video here, and read the team’s paper here.

Cosmography of the Local Universe from Daniel Pomarède on Vimeo.