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Posts Tagged ‘Space’

Planets Weighed Using Pulsar Flashes

23 Aug

The rotating corpses of massive stars can help scientists weigh the planets in the solar system. By carefully timing radio blips from spinning stellar leftovers called pulsars, astronomers have measured the masses of all the planets from Mercury to Saturn, plus all their moons and rings.

Until now, the only way to figure out the mass of a planet was to send a spacecraft past it. The spacecraft’s orbit is determined by the gravitational oomph of the planet (plus whatever moons lay within the spacecraft’s orbit), which in turn depends on the planet’s mass. The new method is the first to let astronomers weigh planets from the comfort of Earthbound observatories.

“That’s what’s remarkable about this technique,” said space technologist William Folkner of NASA’s Jet Propulsion Laboratory, a co-author of a study in the upcoming issue of Astrophysical Journal. “I can’t think of any other way to measure masses of planets from the Earth.” 

The new method relies on the clock-like regularity of a class of neutron stars called pulsars, the rapidly spinning remains of massive stars that died in supernova explosions. Pulsars shoot tight beams of radio waves into space that sweep across the sky like a lighthouse, so from Earth they appear to blink or pulse.

Because the Earth is always moving around the sun, the time it takes for these radio blips to reach us is always changing. To get rid of this effect, astronomers calculate when the pulse should reach the solar system’s center of mass, or barycenter — the point around which all the mass in the solar system moves. But because the planets’ arrangement around the sun is constantly changing, the barycenter moves around with respect to the sun, too.

To pin down the center of mass at a given time, astronomers use a special table of where all the planets are, called an ephemeris, plus values for the masses of the planets taken from previous space missions. If the masses are slightly wrong, then a regular, repeating pattern of timing errors appears in the pulsar data. For instance, if Jupiter’s mass is a bit off, then an error appears every twelve years, once for every time Jupiter orbits the sun. Correcting the value for Jupiter’s mass makes the error disappear.

“You can see that 12 year wiggle in timing of neutron stars,” Folkner said. “That tells you how far the sun is from the solar system barycenter, which tells you what the mass of Jupiter is.”

An international team of scientists used three different radio telescopes, the 1000-foot-wide Arecibo telescope in Puerto Rico, the 210-foot Parkes telescope in Australia and the 328-foot Effelsberg telescope in Germany to time the blips from four different pulsars over a period of 5 to 22 years. They then used computer models to use the pulsars’ times to calculate the masses of Mercury, Venus, Mars, Jupiter and Saturn.

The masses the team found are not as accurate as the best measurements from spacecraft flybys, but they’re close. The measurement for Jupiter, for instance, was found to be 0.0009547921 times the mass of the sun. This value is more accurate than the mass determined from the Pioneer and Voyager spacecraft, and less accurate than, but consistent with, the value from the later Galileo spacecraft, which includes more decimal places.

“Our error bars are larger than those of these spacecraft measurements,” said study co-author Andrea Lommen of Franklin & Marshall College. “We are admitting freely that you should still use the mass of Jupiter measured from the spacecraft, but it’s comforting to know that our measurement agrees with that.”

The new method is also the first that can measure the masses of everything in a planetary system, including moons and rings.

“Spacecraft flybys don’t tell us the mass of everything in the Jupiter system, only the parts inside the spacecraft orbit,” Folkner said. “With this pulsar timing mechanism, we’re sensitive to the entire system, including the moons that are outside the orbit of any spacecraft that have flown by.”

The technique is actually a stepping stone to studying something even more exotic: ripples in space-time called gravitational waves that were predicted by Einstein but have never been observed. The timing of pulsar blips should change slightly whenever a gravitational wave goes by, but in order to see these changes, astronomers have to subtract out all the other noise that could alter the pulsar’s clock.

This study is “a graphic demonstration that you really have to understand the solar system really well if you’re going to be able to confidently detect gravitational radiation,” commented astronomer Scott Tremaine of the Institute for Advanced Study in Princeton, New Jersey, who was not involved in the new work. “If they can continue to develop these techniques to the point where they can detect gravitational waves, that will be a dramatically important event.”

Image: The sun, Earth and Jupiter orbit a common center of mass. David Champion, MPIfR

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Planets Weighed Using Pulsar Flashes

23 Aug

The rotating corpses of massive stars can help scientists weigh the planets in the solar system. By carefully timing radio blips from spinning stellar leftovers called pulsars, astronomers have measured the masses of all the planets from Mercury to Saturn, plus all their moons and rings.

Until now, the only way to figure out the mass of a planet was to send a spacecraft past it. The spacecraft’s orbit is determined by the gravitational oomph of the planet (plus whatever moons lay within the spacecraft’s orbit), which in turn depends on the planet’s mass. The new method is the first to let astronomers weigh planets from the comfort of Earthbound observatories.

“That’s what’s remarkable about this technique,” said space technologist William Folkner of NASA’s Jet Propulsion Laboratory, a co-author of a study in the upcoming issue of Astrophysical Journal. “I can’t think of any other way to measure masses of planets from the Earth.” 

The new method relies on the clock-like regularity of a class of neutron stars called pulsars, the rapidly spinning remains of massive stars that died in supernova explosions. Pulsars shoot tight beams of radio waves into space that sweep across the sky like a lighthouse, so from Earth they appear to blink or pulse.

Because the Earth is always moving around the sun, the time it takes for these radio blips to reach us is always changing. To get rid of this effect, astronomers calculate when the pulse should reach the solar system’s center of mass, or barycenter — the point around which all the mass in the solar system moves. But because the planets’ arrangement around the sun is constantly changing, the barycenter moves around with respect to the sun, too.

To pin down the center of mass at a given time, astronomers use a special table of where all the planets are, called an ephemeris, plus values for the masses of the planets taken from previous space missions. If the masses are slightly wrong, then a regular, repeating pattern of timing errors appears in the pulsar data. For instance, if Jupiter’s mass is a bit off, then an error appears every twelve years, once for every time Jupiter orbits the sun. Correcting the value for Jupiter’s mass makes the error disappear.

“You can see that 12 year wiggle in timing of neutron stars,” Folkner said. “That tells you how far the sun is from the solar system barycenter, which tells you what the mass of Jupiter is.”

An international team of scientists used three different radio telescopes, the 1000-foot-wide Arecibo telescope in Puerto Rico, the 210-foot Parkes telescope in Australia and the 328-foot Effelsberg telescope in Germany to time the blips from four different pulsars over a period of 5 to 22 years. They then used computer models to use the pulsars’ times to calculate the masses of Mercury, Venus, Mars, Jupiter and Saturn.

The masses the team found are not as accurate as the best measurements from spacecraft flybys, but they’re close. The measurement for Jupiter, for instance, was found to be 0.0009547921 times the mass of the sun. This value is more accurate than the mass determined from the Pioneer and Voyager spacecraft, and less accurate than, but consistent with, the value from the later Galileo spacecraft, which includes more decimal places.

“Our error bars are larger than those of these spacecraft measurements,” said study co-author Andrea Lommen of Franklin & Marshall College. “We are admitting freely that you should still use the mass of Jupiter measured from the spacecraft, but it’s comforting to know that our measurement agrees with that.”

The new method is also the first that can measure the masses of everything in a planetary system, including moons and rings.

“Spacecraft flybys don’t tell us the mass of everything in the Jupiter system, only the parts inside the spacecraft orbit,” Folkner said. “With this pulsar timing mechanism, we’re sensitive to the entire system, including the moons that are outside the orbit of any spacecraft that have flown by.”

The technique is actually a stepping stone to studying something even more exotic: ripples in space-time called gravitational waves that were predicted by Einstein but have never been observed. The timing of pulsar blips should change slightly whenever a gravitational wave goes by, but in order to see these changes, astronomers have to subtract out all the other noise that could alter the pulsar’s clock.

This study is “a graphic demonstration that you really have to understand the solar system really well if you’re going to be able to confidently detect gravitational radiation,” commented astronomer Scott Tremaine of the Institute for Advanced Study in Princeton, New Jersey, who was not involved in the new work. “If they can continue to develop these techniques to the point where they can detect gravitational waves, that will be a dramatically important event.”

Image: The sun, Earth and Jupiter orbit a common center of mass. David Champion, MPIfR

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

 
 

Starburst galaxy gives birth to twenty Suns every year [Space Porn]

12 Aug
Say hello to the Haro 11 galaxy, shining brightly from 300 million light-years away. One of the busiest stellar nurseries in the universe, this is one of the youngest examples of a starburst galaxies that is constantly pumping out stars. More »
 
 

Citizen Scientists Make First Deep Space Discovery With Einstein@Home

12 Aug

While your computer is running idle, it could be finding new pulsars and black holes in deep space.

Three volunteers running the distributed computing program Einstein@Home have discovered a new pulsar in the data from the Arecibo Observatory radio telescope. Their computers, one in Iowa (owned by two people) and one in Germany, downloaded and processed the data that found the pulsar, which is in the Milky Way, approximately 17,000 light years from Earth in constellation Vulpecula.

“The way that we found the pulsar using distributed computing with volunteers is a new paradigm that we’re going to make better use of in astronomy as time goes on,” said astronomer Jim Cordes of Cornell University. “This really has legs.”

About 250,000 volunteers run Einstein@Home, on average donating about 250 teraflops of computing power — equivalent to a quarter of the capacity of the largest supercomputer in the world, says program developer David Anderson of University of California at Berkeley’s Space Sciences Laboratory, co-author of the Aug. 12 discovery announcement in Science.

Einstein@Home has been searching for gravitational waves in the data from the US LIGO Observatory since 2005, and since March 2009 has dedicated one-third of its power to searching for radio pulsars and black holes in the Arecibo data. As of this week, it will start dedicating half of its processing power to data from Arecibo, the world’s largest and most sensitive radio telescope, physicist Bruce Allen of the Max Plank Institute for Gravitational Physics in Germany and co-author of the study announced a press conference Aug. 12.

The new pulsar, dubbed PSR J2007+2722, is a neutron star rotating 41 times per second. Pulsars are birthed when stars five to 10 times as massive as our sun explode into a supernova and then collapse into stars composed almost entirely of neutrons.

The data from Arecibo was processed on the computer in Iowa June 11, and then also processed on a computer in Germany June 14 for validation. The finding was part of a larger search that returned results on July 10, which was the first time a human being was aware of the discovery.

Aerial view of the Arecibo Observatory radio telescope.

The person who looked at the results notified Greenbank Observatory in West Virginia, which immediately pointed their telescope at the new pulsar to verify it. Within hours, Arecibo Observatory in Puerto Rico also pointed their telescope at it.

“This is the first time I’ve worked closely with radio astronomers making a discovery,” said Allen. “It was like watching 5-year-olds tearing Christmas presents. Or like watching someone throw chunks of meat at starving sharks.”

Pulsars are named after the pulsing signals they send to Earth. The pulse comes from the spin and the magnetic field of the neutron star being on two different axes, which acts like an electric generator and creates a beamed signal that rotates like a lighthouse. Cordes says theoretical predictions are that only about 20 percent of the pulsars in the galaxy are detectable on Earth because the beam needs to point directly at us to be detected.

Often, pulsars have a companion star or neutron star that was originally born in the same cloud of gas. But this new pulsar doesn’t and is likely a disrupted recycled pulsar. This means the pulsar once had a companion star that it sucked matter from as the star swelled up into a red giant, which caused the pulsar to cycle faster (recycle). The red giant star then exploded into a supernova and blasted the pulsar away, leaving it alone in space (disrupted).

The new pulsar is one of around 2000 pulsars that have been discovered using radio telescopes in the past 43 years, said Cordes. He estimates there are 20,000 pulsars in the Milky Way that could be detected.

“I see this as a long-term effort where we’re going to find really interesting objects,” said Cordes. “We’d like to find a pulsar orbiting a black hole, or a pulsar orbiting another neutron star so that we can test some of Einstein’s predictions of the general theory of relativity”

You can become part of the effort by downloading BOINC. The program has been used to create 70 different distributed computing projects (almost every one in existence except Folding@Home), and you can decide what fraction of your spare computing power you want to dedicate to each of the 70 projects.

In case you need more incentive, Cordes announced that a second pulsar has been already been discovered in the last month by Einstein@Home users in the United Kingdom and Russia. He’s keeping details to himself for now.

“We have a very large data set,” Cordes added at the press conference. “We just need to cull through it, and Einstein@Home lets us use a much finer comb.”

                   

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Images: 1) Screen shot of Einstein@Home/B. Knispel, Albert Einstein Institute. 2) Copyright Cornell University.

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Got a plan to get us back to the Moon? NASA’s got $30 million worth of motivation! [Commercial Spaceflight]

08 Aug
In the clearest indication yet that the future of space exploration lies as much in the private sector as government agencies, NASA announced it's offering $30.1 million for the first commercial group to land a probe on the Moon. More »
 
 

Telescope Images Most Massive Stars Ever Found

21 Jul

Images from the Very Large Telescope in Chile capture the most massive stars ever found, including one twice as large as the current accepted limit for stellar birth weights. This supermassive star, called R136a1, is 265 times the mass of the sun, and was as much as 320 times the mass of the sun when it was born.

This book-of-records-worthy star was found in the young stellar cluster RMC 136a, colloquially known as R136. It is located 165,000 light-years away inside the Tarantula Nebula, in one of our neighboring galaxies, the Large Magellanic Cloud. The star is already a little over a million years old, and has spent most of its life shedding material through powerful stellar winds and outflows of gas. It has lost a fifth of its initial mass.

Astronomers had previously believed that the upper limit on stars’ masses at birth was 150 solar masses, but four stars in the cluster had birth weights well above that limit. Although the cluster houses more than 100,000 stars, those four giants account for nearly half the wind and radiation power of the entire group.

This trio of images shows a visible-light image of the Tarantula nebula as seen with the Wide Field Imager on the MPG/ESO 2.2-meter telescope (left) along with a zoomed-in visible-light image from the Very Large Telescope (middle). A new image of the R136 cluster, taken with a near-infrared instrument on the Very Large Telescope, is shown in the right-hand panel, with the cluster itself at the lower right.

Below, an artist’s conception shows the relative sizes of stars, from red dwarfs of about 0.1 solar masses, yellow dwarfs like the sun, blue dwarfs weighing eight solar masses, and the approximately 300-solar-mass R136a1.

Images: 1) ESO/P. Crowther/C.J. Evans. 2) ESO/M. Kornmesser

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Asteroid mining will give us all the platinum we’ll ever need, and maybe start a new Space Age [Asteroid Mining]

19 Jul
The platinum group metals are crucial to electronics, massively expensive, and extremely rare on this planet. But on asteroids? A single one holds billions of pounds of these metals - and that could start the era of private space exploration. More »
 
 

Our Eavesdropping-on-ET Strategy Not Likely to Work

14 Jul

Bad news for SETI: Even with the most sensitive radio telescopes yet designed, humans probably won’t find intelligent aliens by listening in on their phones and televisions, a new study finds.

“Eavesdropping on ET is very hard, even with the latest radio telescopes,” said astronomer Duncan Forgan of the University of Edinburgh, a coauthor of the study. “If we don’t try any other ways of searching for aliens, then we may never find them.”

Forgan and astronomer Robert Nichol of the Institute of Cosmology and Gravitation in the U.K. set out to test the suggestion that rather than building expensive telescopes dedicated exclusively to listening for signals from aliens, SETI — the search for extra-terrestrial intelligence — could be done on the cheap by piggy-backing on other astronomy missions.

Some astronomers hoped SETI searches could ride on the coattails of the planned Square Kilometer Array, which will probe the history of the universe with thousands of small antennas spread out either Australia or South Africa.

“We focused on the SKA because it will be an incredible advancement in radio astronomy,” Forgan said. “It will be the most powerful radio telescope ever built.”

The SKA will also be sensitive in the same frequency range that cellphones, radio and television operate in. If the aliens out there are anything like us, that frequency range is exactly where we should expect to find them, astronomers have suggested.

In 2007, astrophysicists Abraham Loeb and Matias Zaldarriaga of the Harvard-Smithsonian Center for Astrophysics calculated that signals similar to those used in human military radar could be detected from more than 160 light-years away using a telescope in the Netherlands called LOFAR, and more than 650 light-years away using the SKA.

But assuming these aliens have technology like ours, there won’t be enough time to find them, Forgan and Nichol argue. Humans, the only intelligent civilization we know of, have been communicating using radio waves for only about 100 years — and we’re beginning to go quiet. Advances in technology mean less power is needed to broadcast, and digital communication is starting to replace radio altogether.

Forgan and Nichol randomly generated about 500,000 alien civilizations based on current theories of planet formation, and an optimistic guess as to how many would develop life. They then assumed that each civilization broadcasts in radio for 100 years, and they can hear each other from up to 300 light-years away.

“All communication disappears,” the team wrote. Even with a telescope like the SKA, the odds of eavesdropping on another civilization are one in 10 million. The results were posted in a paper on the astronomy preprint website arxiv.org and accepted for publication in the International Journal of Astrobiology.

A more fruitful strategy would be to target our searches, Forgan suggests. We may not be able to hear leaked signals, but we could still pick up a deliberate beacon from a civilization that wanted to announce its presence. A telescope dedicated to searching for such a beacon, like the Allen Telescope Array in northern California, would improve the odds to one in 10 thousand.

Jill Tarter of the SETI Institute thinks Forgan underestimates the usefulness of the SKA. “The SKA is being built with a large field of view and many simultaneous beams, so that there should in fact be significant observing time available for SETI,” she said.

Whatever the odds, Loeb thinks we should eavesdrop, anyway. “Rather than speculate about how generic is our own evolution and whether others will be the same, we should just search,” he said. He points out that a lot of technological advances are driven by social forces. For example, Earth gave off the most radio waves during the Cold War, when radar ballistic missile searches were common.

“Politics are impossible to predict, they don’t follow laws of physics,” he said. “We should just explore the sky, and try to set as strong limits as we can.”

Forgan agrees. “We should always continue to eavesdrop as it is a cheap search method, especially if we piggy-back,” he said. “If you don’t listen, you won’t hear anything.”

Image: SKA

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Planck’s first image of space, past and present

05 Jul
planck.jpg

The European Space Agency today released the first image of space obtained by the Planck mission. Shown above, the image includes emissions from dust in our own galaxy and faint ripples of the cosmic microwave background that is light left behind from The Big Bang. This is the first all-sky map from the spacecraft, which will complete four surveys before its mission ends in 2012. A good explanatory article here on SpaceFlight Now. (image courtesy ESA/ LFI & HFI Consortia; Thanks, Dave Clements)

 
 

How do we measure gravitational waves? [Mad Science]

03 Jul
"Gravitational telescopes" let scientists observe fluctuations in spacetime itself. They are, in a word, crazystupidamazing. More »