RSS
 

Posts Tagged ‘Space’

Hundred Year Starship Initiative plans to put people on Mars by 2030, bring them back by… well, never (video)

31 Oct
For a while now, there has been a conversation going on in certain circles (you know, space circles): namely, if the most prohibitive part of a manned flight to Mars would be the return trip, why bother returning at all? And besides the whole "dying alone on a hostile planet 55-million-plus kilometers from your family, friends, and loved ones" thing, we think it's a pretty solid consideration. This is just one of the topics of discussion at a recent Long Now Foundation event in San Francisco, where NASA Ames Research Center Director Pete Worden discussed the Hundred Year Starship Initiative, a project NASA Ames and DARPA are undertaking to fund a mission to the red planet by 2030. Indeed if the space program "is now really aimed at settling other worlds," as Worden said, what better way to encourage a permanent settlement than the promise that there will be no coming back -- unless, of course, they figure out how to return on their own. Of course, it's not like they're being left to die: the astronauts can expect supplies from home while they figure out how to get things up and running. As Arizona State University's Dr. Paul Davies, author of a recent paper in Journal of Cosmology, writes, "It would really be little different from the first white settlers of the North American continent, who left Europe with little expectation of return." Except with much less gravity. See Worden spout off in the video after the break.

Continue reading Hundred Year Starship Initiative plans to put people on Mars by 2030, bring them back by... well, never (video)

Hundred Year Starship Initiative plans to put people on Mars by 2030, bring them back by... well, never (video) originally appeared on Engadget on Sun, 31 Oct 2010 03:03:00 EDT. Please see our terms for use of feeds.

Permalink PopSci, AOL News  |  sourceKurzweil AI  | Email this | Comments
 
 

We may be even more alone in the universe than we thought [Evolution]

22 Oct
Two scientists propose that the jump from bacteria to complex life might be much riskier than previously imagined. Even on planets with earthlike conditions, plant and animal life would therefore be incredibly rare. More »
 
 

The golden age (is ending)

21 Oct

As has been oft remarked on this blog, we are in a golden age of astrophysics and cosmology. The data is pouring down from the heavens, in large part from 14 state-of-the-art NASA space telescopes. However, this cornucopia of astronomy is about to come to a crashing stop. We are at the high-water mark, and the next few years are going to see a rapid decline in the number of observatories in space. In five years most, if not all, of these telescopes will be defunct (WMAP is already in the graveyard), and it’s not clear what will be replacing them. This is brought into startling focus by the following plot:
NASA space missions
The dotted line shows “today”. In a few years, the only significant US space observatory may be the James Webb Space Telescope (assuming it’s on budget and on time, neither of which are to be taken for granted). The reasons for the current “bubble” in resources, and the impending crash, are myriad and complex. These missions take many years, if not multiple decades, to plan and execute, and we are currently reaping the harvest of ancient boom times. But one aspect subtly implied by this graph is the impact of JWST on space funding. The cost of this mission is now over $5 billion, and continues to rise. Very optimistically, the mission will be in space in 2014, and will continue to consume major developmental resources until then. In an era of fiscal austerity, it is difficult to imagine that the immense ongoing cost of JWST leaves room for much else to be done. The community has gone through the painful exercise of winnowing down its “wish list” to a few key, high-impact missions (as detailed by Julianne here, here, and here; my summary here). It is not immediately apparent that even this fairly “modest” list is attainable given current budget realities. Astronomical data from space over the next decade will pale in comparison to the previous one. We are at a unique moment in the history of space astronomy; it is highly unlikely that we will have fourteen major space astrophysics missions flying again within our lifetimes. We need to make the most of what we have, while we still have it.

 
 

Incoming Cosmic Rays Hit Record High

19 Oct

The Earth was pummeled with record-setting levels of cosmic rays in 2009. Measurements from NASA’s Advanced Composition Explorer (ACE) and other spacecraft found that more high-energy particles from galactic space penetrated the inner solar system in the last few years than at any other time since the beginning of the space age.

The spike is almost certainly due to several weird aspects of the most recent solar minimum, and could be the start of a new normal for cosmic ray levels.

“It’s sort of like everything’s working in the same direction right now, to allow cosmic rays greater access to the inner solar system,” said space scientist Richard Mewaldt of Caltech. Mewaldt and colleagues published their findings Oct. 7 in Astrophysical Journal Letters.

Cosmic rays, high-energy particles that originate in the galaxy and smack into Earth from all directions at near-light speeds, can pose a danger to spacecraft and astronauts spending long periods of time outside the Earth’s protective magnetic field. Most of these particles, especially the less-energetic ones, are deflected by the solar wind, which blows a protective bubble around the solar system called the heliosphere.

This solar system shield fluctuates in effectiveness every 11 years, as the sun goes through its regular cycle from lots of sunspots and solar flares to relatively boring solar weather. When the sun is most active, the solar wind is strongest, and even fewer cosmic rays penetrate the barriers. At solar minimum, more cosmic rays make it through.

“Up until now they had been reaching a constant level each solar minimum,” Mewaldt said. “But this one was different. This cycle, they’re more intense than they were in the past.”

The most recent solar minimum started in 2006 and was expected to end in 2008, but the sun stayed quiet through 2010. Using data from the ACE spacecraft, which has been in orbit around the sun since 1997, and historical data from a series of short-lived spacecraft going back to 1965, Mewaldt and colleagues showed that the cosmic ray levels in 2009 were 20 to 26 percent greater than at any previous solar minimum.

There are three main reasons for the upswing in cosmic rays, Mewaldt said. The solar magnetic field has been weaker than usual, which means the magnetic field that permeates the solar system is weaker too, and less efficient at knocking cosmic rays aside.

The long years of low solar activity also contribute to the high cosmic ray numbers. The sun occasionally lets off enormous bursts of plasma called coronal mass ejections, which can block cosmic rays as they explode out into interplanetary space. But there were fewer of these bursts during the most recent solar minimum, and those that happened were smaller than usual. “That’s another thing that let down the barriers and let the cosmic rays come in easier,” Mewaldt said.

Finally, the constant stream of charged particles that makes up the solar wind is weaker, making the protective bubble of the heliosphere smaller and more permeable. Incoming cosmic rays have a shorter distance to go to reach the Earth, so wimpier particles that would normally never get here can now make the journey.

Astronomers have already seen the impact of these extra cosmic rays on spacecraft, which have shown a 25 percent increase in certain types of errors that result from cosmic ray strikes, Mewaldt says.

The increased cosmic rays could pose a bigger problem for astronauts heading to Mars or building a base on the moon.

“They’d feel the brunt of this radiation for a longer period,” Mewaldt said “It’s already a problem, this would just make it worse.”

Although cosmic ray levels started going back down in early 2010, Mewaldt thinks the new high could be part of the long-term pattern of the sun. Measurements of radioactive elements embedded in ice cores at the poles show that over the past 500 years, cosmic ray levels were 40 to 80 percent higher than in the early 1970s. That means the sun was quieter in the past than it has been in the last few decades.

“It could well be that we are going to one of these longer-term grand minima,” Mewaldt said. “We don’t know yet for sure if we’re starting into one of those periods, but it certainly looks possible. We’ll have to wait a little longer to say.”

“I believe that this paper is the first paper that really shows us how the heliosphere works as a big global system,” commented NASA astronomer William D. Pesnell. “I think it will become an important paper because of that.”

Image: NASA

See Also:

Follow us on Twitter @astrolisa and @wiredscience, and on Facebook.

 
 

Directly Observing Exoplanets Just Got Easier [Astronomy]

17 Oct
So that Gliese Goldilocks Zone planet may not exist. Sad. Cheer up though, because Arizona University astronomers have discovered a new technique that could make spotting exoplanets a bit easier. Which is great, because right now it's really frickin' hard. More »


 
 

Cold, Dead Stars Could Help Limit Dark Matter

15 Oct

Hunting for cold stellar corpses near the center of the galaxy or in star clusters could put new limits on the properties of dark matter.

“You can exclude a big class of theories that the experiments cannot exclude just by observing the temperature of a neutron star,” said physicist Chris Kouvaris of the University of Southern Denmark, lead author of a paper in the Sept. 28 Physical Review D. “Maybe by observations, which come cheaper than expensive experiments, we might get some clues about dark matter.”

Dark matter is the irritatingly invisible stuff that makes up some 23 percent of the universe, but makes itself known only through its gravitational tug on ordinary matter.

There are several competing theories about what dark matter actually is, but one of the most widely pursued is a hypothetical weakly interacting massive particle (WIMP). Physicists in search of WIMPs have placed experimental detectors deep underground in mines and mountains, and are waiting for a dark matter particle to hit them.

Others have proposed looking for the buildup of dark matter in stars like the sun or white dwarfs. But both subterranean and stellar-detection strategies will light up only for WIMPs larger than a certain size. That size is miniscule — about a trillionth of a quadrillionth of a square centimeter — but dark matter particles could be smaller still.

One way to rule out such diminutive particles is to look to neutron stars, suggest Kouvaris and co-author Peter Tinyakov of the Université Libre de Bruxelles in Belgium.

Neutron stars are the cold, dense remnants of massive stars that died in fiery supernova explosions. They tend to have masses similar to the sun, but in diameter they would barely stretch from one end of Manhattan to the other. This extreme density makes neutron stars exceptionally good nets for dark matter.

“For their size and their temperature, they have the best efficiency in capturing WIMPs,” Kouvaris said. Particles up to 100 times smaller than the ones underground experiments are sensitive to could still make a noticeable difference to neutron stars.

After the fires of their birth, neutron stars slowly cool over millions of years as they radiate photons. But if WIMPs annihilate each other whenever they meet — like a particle of matter meeting a particle of antimatter — as some models suggest they should, dark matter could reheat these cold stars from the inside.

Kouvaris calculated the minimum temperature for a WIMP-burning neutron star, and found it to be about 100,000 kelvins [about 180,000 degrees Fahrenheit]. That’s more than 10 times hotter than the surface of the sun, but more than 100 times cooler than the sun’s fuel-burning interior. It’s also much cooler than any neutron star yet observed.

Dark matter and ordinary matter are thought to clump up in some of the same places, like the center of the galaxy or globular clusters of stars. So Kouvaris and Tinyakov suggest that astronomers try to find a neutron star colder than the minimum temperature in a region with a lot of dark matter floating around.

“If you observe a neutron star with a temp below the one we predict, that excludes a whole class of dark-matter candidates,” Kouvaris said. It could mean the WIMPs are extra-small, or that they don’t annihilate when they meet each other — a property of WIMPs that experiments can’t get at.

“It’s an intriguing idea,” said observational astronomer David Kaplan University of Wisconsin-Milwaukee. “But I’m a little skeptical that it can be done immediately, or even in the near future.”

The center of the galaxy is dusty and difficult to observe, and most globular clusters are so far away that a cold, tiny neutron star hiding inside them would be beyond today’s telescopes. The next generation of ultraviolet telescopes could be up to the task, Kaplan suggests. “But that’s not to say that it will be easy.”

Astronomer Bob Rutledge of McGill University suggests an alternative approach: Rather than squinting for neutron stars’ dim light, astronomers could find them through ripples in space-time called gravitational waves. When two neutron stars merge, they are expected to throw off massive amounts of these waves, and Earth-based detectors like LIGO are already in place to catch them — although no waves have actually shown up yet.

“It would be technically hard, but a sound approach,” Rutledge said. “This sort of thing could become possible in the more distant future.”

Image: Artist’s impression of a neutron star with a powerful magnetic field, called a magnetar. Credit: NASA

See Also:

Follow us on Twitter @astrolisa and @wiredscience, and on Facebook.

 
 

Cosmic strings are super-massive, ultra-thin cracks in the universe [Mad Astrophysics]

12 Oct
Cosmic strings are theoretical fault lines in the universe, defective links between different regions of space created in the moments after the Big Bang. And they might be theoretical no longer - distant quasars show the fingerprints of these strings. More »
 
 

Extreme black holes billions of years ago overheated the universe [Mad Astrophysics]

08 Oct
Global warming really isn't just a local problem...universal warming ran through the universe 11 billion years ago, doubling the temperature of intergalactic helium. The cosmic temperature spike was so bad, it stopped galaxies from developing for 500 million years. More »
 
 

Solar System’s Deepest Canyon Sinks Miles Into Mars

08 Oct

Mars Valles Marineris rift valley

On the Martian surface, the mountains are high and the canyons are low. Really, really low.

Not only is the martian volcano Olympus Mons the highest peak in the solar system, Melas Chasma, the canyon pictured above, is the deepest in the solar system. In this image from the European Space Agency’s Mars Express orbiter, the valley on the left (darker area) sits a whopping 5.6 miles below the plateau on the right (lighter area).

Compared to the average shape of Mars, known as the “aeroid,” the canyon floor sinks down about 3.1 miles. Planetary scientists would love to use sea level measurements to describe Martian surface features, but there’s no ocean on the red planet anymore and any signs of an ocean are long since warped by millions of years of surface deformation.

The photo above covers about 7,700 square miles, or about the size of New Jersey, which makes it only a tiny postage stamp of Mars’ deepest, longest and most prominent scar — the 2,500-mile-long Valles Marineris rift valley (below).

Valles Marineris rift copyright of JPL

ESA also released the following 3-D rendering of Melas Chasma in addition to the satellite imagery, revealing the valley in all its topographical glory (via Nancy Atkinson at Universe Today).

Melas Chasma 3-D

Images: 1) Melas Chasma – high-resolution image, ESA/DLR/FU Berlin (G. Neukum), 2) Viking 1 and 2 orbiter image collage of Valles Marineris canyon – high-resolution image. Courtesy NASA/JPL-Caltech, 3) Melas Chasma – high-resolution image, ESA/DLR/FU Berlin (G. Neukum),

See Also:

Follow us on Twitter @davemosher and @wiredscience, and on Facebook.

 
 

We won’t reach Alpha Centauri until the 24th century…unless we have an energy breakthrough [Mad Science]

27 Sep
If you take humanity's current energy and technological capacity and project a steady increase into the future, the chances of us reaching the stars any time soon look bleak. Even our nearest stellar neighbor is at least 300 years away. More »