Supernova Explodes Inside a Nebula

Image credit: LBL
By measuring polarized light from an unusual exploding star, an international team of astrophysicists and astronomers has worked out the first detailed picture of a Type Ia supernova and the distinctive star system in which it exploded.

Using the European Southern Observatory’s Very Large Telescope in Chile, the researchers determined that supernova 2002ic exploded inside a flat, dense, clumpy disk of dust and gas, previously blown away from a companion star. Their work suggests that this and some other precursors of Type Ia supernovae resemble the objects known as protoplanetary nebulae, well known in our own Milky Way galaxy.

Lifan Wang of Lawrence Berkeley National Laboratory, Dietrich Baade of the European Southern Observatory (ESO), Peter H?flich and J. Craig Wheeler of the University of Texas at Austin, Koji Kawabata of the National Astronomical Observatory of Japan, and Ken’ichi Nomoto of the University of Tokyo report their findings in the 20 March 2004 issue of Astrophysical Journal Letters.

Casting supernovae to type
Supernovae are labeled according to the elements visible in their spectra: Type I spectra lack hydrogen lines, while Type II spectra have these lines. What makes SN 2002ic unusual is that its spectrum otherwise resembles a typical Type Ia supernova but exhibits a strong hydrogen emission line.

Type II and some other supernovae occur when the cores of very massive stars collapse and explode, leaving behind extremely dense neutron stars or even black holes. Type Ia supernovae, however, explode by a very different mechanism.

“A Type Ia supernova is a metallic fireball,” explains Berkeley Lab’s Wang, a pioneer in the field of supernova spectropolarimetry. “A Type Ia has no hydrogen or helium but lots of iron, plus radioactive nickel, cobalt, and titanium, a little silicon, and a bit of carbon and oxygen. So one of its progenitors must be an old star that has evolved to leave behind a carbon-oxygen white dwarf. But carbon and oxygen, as nuclear fuels, do not burn easily. How can a white dwarf explode?”

The most widely accepted Type Ia models assume that the white dwarf — roughly the size of Earth but packing most of the mass of the sun — accretes matter from an orbiting companion until it reaches 1.4 solar masses, known as the Chandrasekhar limit. The now superdense white dwarf ignites in a mighty thermonuclear explosion, leaving behind nothing but stardust.

Other schemes include the merger of two white dwarfs or even a lone white dwarf that re-accretes the matter shed by its younger self. Despite three decades of searching, however, until the discovery and subsequent spectropolarimetric studies of SN 2002ic, there was no firm evidence for any model.

In November of 2002, Michael Wood-Vasey and his colleagues in the Department of Energy’s Nearby Supernova Factory based at Berkeley Lab reported the discovery of SN 2002ic, shortly after its explosion was detected almost a billion light-years away in an anonymous galaxy in the constellation Pisces.

In August of 2003, Mario Hamuy from the Carnegie Observatories and his colleagues reported that the source of the copious hydrogen-rich gas in SN 2002ic was most likely a so-called Asymptotic Giant Branch (AGB) star, a star in the final phases of its life, with three to eight times the mass of the sun — just the sort of star that, after it has blown away its outer layers of hydrogen, helium, and dust, leaves behind a white dwarf.

Moreover, this seemingly self-contradictory supernova — a Type Ia with hydrogen — was in fact similar to other hydrogen-rich supernovae previously designated Type IIn. This in turn suggested that, while Type Ia supernovae are indeed remarkably similar, there may be wide differences among their progenitors.

Because Type Ia supernovae are so similar and so bright — as bright or brighter than whole galaxies — they have become the most important astronomical standard candles for measuring cosmic distances and the expansion of the universe. Early in 1998, after analyzing dozens of observations of distant Type Ia supernovae, members of the Department of Energy’s Supernova Cosmology Project based at Berkeley Lab, along with their rivals in the High-Z Supernova Search Team based in Australia, announced the astonishing discovery that the expansion of the universe is accelerating.

Cosmologists subsequently determined that over two-thirds of the universe consists of a mysterious something dubbed “dark energy,” which stretches space and drives the accelerating expansion. But learning more about dark energy will depend on careful study of many more distant Type Ia supernovae, including a better knowledge of what kind of star systems trigger them.

Picturing structure with spectropolarimetry
The spectropolarimetry of SN 2002ic has provided the most detailed picture of a Type Ia system yet. Polarimetry measures the orientation of light waves; for example, Polaroid sunglasses “measure” horizontal polarization when they block some of the light reflected from flat surfaces. In an object like a cloud of dust or a stellar explosion, however, light is not reflected from surfaces but scattered from particles or from electrons.

If the dust cloud or explosion is spherical and uniformly smooth, all orientations are equally represented and the net polarization is zero. But if the object is not spherical — shaped like a disk or a cigar, for example — more light will oscillate in some directions than in others.

Even for quite noticeable asymmetries, net polarization rarely exceeds one percent. Thus it was a challenge for the ESO spectropolarimetry instrument to measure faint SN 2002ic, even using the powerful Very Large Telescope. It took several hours of observation on four different nights to acquire the necessary high-quality polarimetry and spectroscopy data.

The team’s observations came nearly a year after SN 2002ic was first detected. The supernova had grown much fainter, yet its prominent hydrogen emission line was six times brighter. With spectroscopy the astronomers confirmed the observation of Hamuy and his associates, that ejecta expanding outward from the explosion at high velocity had run into surrounding thick, hydrogen-rich matter.

Only the new polarimetric studies, however, could reveal that most of this matter was shaped as a thin disk. The polarization was likely due to the interaction of high-speed ejecta from the explosion with the dust particles and electrons in the slower-moving surrounding matter. Because of the way the hydrogen line had brightened long after the supernova was first observed, the astronomers deduced that the disk included dense clumps and had been in place well before the white dwarf exploded.

“These startling results suggest that the progenitor of SN 2002ic was remarkably similar to objects that are familiar to astronomers in our own Milky Way, namely protoplanetary nebulae,” says Wang. Many of these nebulae are the remnants of the blown-away outer shells of Asymptotic Giant Branch stars. Such stars, if rotating rapidly, throw off thin, irregular disks.

A matter of timing
For a white dwarf to collect enough material to reach the Chandrasekhar limit takes a million years or so. By contrast, an AGB star loses copious amounts of matter relatively quickly; the protoplanetary-nebula phase is transitory, lasting only a few hundreds or thousands of years before the blown-off matter dissipates. “It’s a small window,” says Wang, not a long enough time for the leftover core (itself a white dwarf) to re-accrete enough material to explode.

Thus it’s more likely that a white dwarf companion in the SN 2002ic system was already busily collecting matter long before the nebula formed. Because the protoplanetary phase lasts only a few hundred years, and assuming a Type Ia supernova typically takes a million years to evolve, only about a thousandth of all Type Ia supernovae are expected to resemble SN 2002ic. Fewer still will exhibit its specific spectral and polarimetric features, although “it would be extremely interesting to search for other Type Ia supernovae with circumstellar matter,” Wang says.

Nevertheless, says Dietrich Baade, principal investigator of the polarimetry project that used the VLT, “it’s the assumption that all Type Ia supernovae are basically the same that permits the observations of SN 2002ic to be explained.”

Binary systems with different orbital characteristics and different kinds of companions at different stages of stellar evolution can still give rise to similar explosions, through the accretion model. Notes Baade, “The seemingly peculiar case of SN 2002ic provides strong evidence that these objects are in fact very much alike, as the stunning similarity of their light curves suggests.”

By showing the distribution of the gas and dust, spectropolarimetry has demonstrated why Type Ia supernovae are so much alike even though the masses, ages, evolutionary states, and orbits of their precursor systems may differ so widely.

The Berkeley Lab is a U.S. Department of Energy national laboratory located in Berkeley, California. It conducts unclassified scientific research and is managed by the University of California. Visit our website at http://www.lbl.gov.

Original Source: Berkeley Lab News Release

Opportunity’s Out of the Crater

Image credit: NASA/JPL
The Mars Exploration Rover Opportunity’s landing site is now viewable in panorama as the rover exited the crater which scientists consider one of the investigative landmarks on the red planet.

This image mosaic, compiled from navigation and panoramic camera images during the 33rd, 35th, and 36th sols on Mars, shows a panoramic view of the crater where the rover had been exploring since its dramatic arrival in late January 2004.

The crater, now informally referred to as “Eagle Crater,” is approximately 22 meters (72 feet) in diameter. Opportunity’s lander is visible in the center of the image. Track marks reveal the rover’s progress. The rover cameras recorded this view as Opportunity climbed close to the crater rim as part of a soil survey campaign.

After a slightly slippery start yestersol, Opportunity made it out of “Eagle Crater”on sol 57, which ends at 8:45 p.m. PST on March 22. The drive along the crater’s inner slope that was initiated on the last sol continued this sol until Opportunity exited its landing-site crater.

The rover tried driving uphill out of its landing-site crater during its 56th sol, ending at 10:05 p.m. March 21, PST, but slippage prevented success.

The rover remained healthy, and it later completed a turn to the right and a short drive along the crater’s inner slope.

Controllers sent it on a different route for exiting the crater and images from the navigation camera confirmed that the rover is now about 9 meters (about 29.5 feet) outside of the crater.

The rover also conducted remote sensing observations between naps this sol. After completing the drive out of the crater, the navigation camera imaged Opportunity’s brand new view of the plains of Meridiani Planum.

Opportunity flipped more meters on its odometer during the latest drives along the current soil survey campaign, surpassing the total drive distance of 1997’s Sojourner rover.

During the martian night, rover planners will awaken Opportunity to take miniature thermal emission spectrometer observations of the ground and the atmosphere.

Original Source: Astrobiology Magazine

Five Years of Universe Today

In case you weren’t counting, today marks the fifth anniversary of Universe Today. That’s right, I started this space web rag on March 22, 1999 as a hobby; an excuse for me to learn more about web publishing and online marketing. Little did I realize I’d still be working on it five years later. 🙂 I never dreamed I’d have more than a few hundred subscribers, but there are now 21,000 of you signed up to get the email edition.

Since I began Universe Today, I’ve moved servers seven times, had two children, lost two hard drives, published 805 newsletters, worked at three different jobs, and served up about 200 million “hits”. There have been a few dry spells, too, when I didn’t have the time or enthusiasm to work on the website – the last year’s been a blast though. If you want to take a look back at the history of the website, here’s a handy link through the Wayback Machine. I know, I know, it started out pretty ugly.

So, I just wanted to take a moment and thank everyone for your enthusiastic support, engaging conversation in the forum, and gentle feedback at my tpyos. I’d also like to thank my sponsors (especially Countdown Creations, who’s been a big contributor right from the beginning).

Here’s to many, many more years.

Fraser Cain
Publisher
Universe Today

A New Look at McNeil’s Nebula

Image credit: Gemini
A timely discovery by American amateur astronomer Jay McNeil, followed immediately by observations at the Gemini Observatory, has provided a rare glimpse into the slow, yet violent birth of a star about 1,500 light-years away. The resulting findings reveal some of the strongest stellar winds ever detected around an embryonic Sun-like star.

McNeil?s find was completely serendipitous. He was surveying the sky in January from his backyard in rural Kentucky and taking electronic images through his 3-inch (8-centimeter) telescope. When he examined his work, he noticed a small glowing smudge of light in the constellation of Orion that wasn?t there before. ?I knew this part of the sky very well and I couldn?t believe what I was seeing,? said McNeil. Astronomers were alerted almost immediately, via the Internet, and quickly realized that he had come across something special.

?It is extremely rare that we have an opportunity to study an important event like this, where a newly born star erupts and sheds light on its otherwise dark stellar nursery,? said Gemini astronomer Dr. Colin Aspin. Dr. Aspin and Dr. Bo Reipurth, (of the University of Hawaii?s Institute for Astronomy), published the first paper on this object, now known as McNeil?s Nebula. Their work, based on observations using the Frederick C. Gillett Gemini North Telescope on Mauna Kea, is in press for Astrophysical Journal Letters.

?McNeil?s Nebula is allowing us to add another important piece to the puzzle of the long, protracted birth of a star,? said Reipurth. ?It has been more than thirty years since anything similar has been seen, so for the first time, we have an opportunity to study such an event with modern instrumentation like that available at Gemini.?

Detailed images and spectra of the stellar newborn, taken using the Gemini Near-Infrared Imager and Multi-Object Spectrograph, demonstrate that the star has brightened considerably. It is blasting gas away from itself at speeds of more than 600 kilometers per second (over 2000 times faster than a typical commercial airplane). The observations indicate the eruption was triggered by complex interactions in a rotating disk of gas and dust around the star. For reasons that are still not fully understood, the inner part of the disk begins to heat up, causing the gases to glow. At the same time, some gas funnels along magnetic field lines onto the surface of the star, creating very bright hot spots and causing the star to grow. The eruption also cleared out some of the dust and gas surrounding the young star, allowing light to escape and illuminate a cone-shaped cavity carved out by previous eruptions into the gas.

The birth of a star takes several tens of thousands of years and these observations are but a brief snapshot of the process. Although this is very a rapid schedule on astronomical time scales, Reipurth explained that it?s impossibly slow compared to a human lifetime. ?We astronomers therefore have no choice but to compare various objects where each one is in a different state of development,? he said. ?This is very similar to the imaginary situation of an alien landing on Earth with only half an hour to understand the full life cycle of humans. By looking at people of various ages and using some logic, this alien could piece together our growth from infant to old age. This is how we are beginning to understand the birth and youth of stars. Rare events like the one McNeil discovered help to fill in the blanks in our understanding of stellar origins.?

This outburst may not be the first time the star has flared during its long tumultuous birth. Following McNeil?s discovery, an inspection of archival plates revealed that a similar event took place in 1966, when the star flared and faded again into its enshrouding gas. ?We know so little about these kind of eruptions that we cannot even say whether the star will continue to flare or will rapidly fade from view again,? said Aspin. ?We were extremely fortunate that Mr. McNeil discovered this when he did. In an event like this, the earlier we can observe it, the better our chances are of understanding what is going on.?

Fortunately for Aspin and Reipurth, McNeil discovered this in the early winter while the Orion region is still high in the night-time sky. It was also fortunate that McNeil was so familiar with this part of the sky that he noticed right away that something had changed. This combination of circumstances enabled the astronomers to prepare an observation run on Gemini very quickly. ?Our window for observing this object is closing rapidly but it will become visible again later this year,? said Aspin. ?By then this eruption could be over.?

A striking color image from Gemini reveals fine details in McNeil?s Nebula. The star and its bright disk shine like a lighthouse through the cavity of gas and dust. The Gemini image and an artist?s conception of how the escaping gas and hotspots on a young star might have caused this event can be found here.

The Gemini Observatory is an international collaboration that has built two identical 8-meter telescopes. The Frederick C. Gillett Gemini Telescope is located on Mauna Kea, Hawai`i (Gemini North) and the Gemini South telescope is located on Cerro Pach?n in central Chile (Gemini South), and hence provide full coverage of both hemispheres of the sky. Both telescopes incorporate new technologies that allow large, relatively thin mirrors under active control to collect and focus both optical and infrared radiation from space.

The Gemini Observatory provides the astronomical communities in each partner country with state-of-the-art astronomical facilities that allocate observing time in proportion to each country’s contribution. In addition to financial support, each country also contributes significant scientific and technical resources. The national research agencies that form the Gemini partnership include: the US National Science Foundation (NSF), the UK Particle Physics and Astronomy Research Council (PPARC), the Canadian National Research Council (NRC), the Chilean Comisi?n Nacional de Investigaci?n Cientifica y Tecnol?gica (CONICYT), the Australian Research Council (ARC), the Argentinean Consejo Nacional de Investigaciones Cient?ficas y T?cnicas (CONICET) and the Brazilian Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico (CNPq). The Observatory is managed by the Association of Universities for Research in Astronomy, Inc. (AURA) under a cooperative agreement with the NSF. The NSF also serves as the executive agency for the international partnership.

The Institute for Astronomy at the University of Hawaii conducts research into galaxies, cosmology, stars, planets, and the sun. Its faculty and staff are also involved in astronomy education, deep space missions, and in the development and management of the observatories on Haleakala and Mauna Kea. Refer to http://www.ifa.hawaii.edu/ for more information about the Institute.

Original Source: Gemini Observatory News Release

Saturn With Cassini’s Blue Filter

Image credit: NASA/JPL
Bands and spots in Saturn’s atmosphere, including a dark band south of the equator with a scalloped border, are visible in this image from the Cassini-Huygens spacecraft.

The narrow-angle camera took the image in blue light on Feb. 29, 2004. The distance to Saturn was 59.9 million kilometers (37.2 million miles). The image scale is 359 kilometers (223 miles) per pixel.

Three of Saturn’s moons are seen in the image: Enceladus (499 kilometers, or 310 miles across) at left; Mimas (398 kilometers, or 247 miles across) left of Saturn’s south pole; and Rhea (1,528 kilometers, or 949 miles across) at lower right. The imaging team enhanced the brightness of the moons to aid visibility.

The BL1 broadband spectral filter (centered at 451 nanometers) allows Cassini to “see” light in a part of the spectrum visible as the color blue to human eyes. Scientist can combine images made with this filter with those taken with red and green filters to create full-color composites.

In this image, everything on the planet is a cloud, and the contrast between bright and dark features is determined by the different blue-light absorbing properties of the particles that comprise the clouds. White regions contain material reflecting in the blue; dark regions contain material absorbing in the blue. This reflecting/absorbing behavior is controlled by the composition of the cloud’s colored material, which is still a mystery — one which may be answered by Cassini. The differing concentrations of this material across the planet are responsible for its banded appearance in the visible region of the electromagnetic spectrum.

The Cassini-Huygens mission is a cooperative project of NASA, the European Space Agency and the Italian Space Agency. The Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, manages the Cassini-Huygens mission for NASA’s Office of Space Science, Washington, D.C. The imaging team is based at the Space Science Institute, Boulder, Colo.

For more information about the Cassini-Huygens mission visit, http://saturn.jpl.nasa.gov and the Cassini imaging team home page, http://ciclops.org .

Original Source: CICLOPS News Release

Does Io Look Like an Early Earth?

Image credit: NASA/JPL
Investigations into lava lakes on the surface of Io, the intensely volcanic moon that orbits Jupiter, may provide clues to what Earth looked like in its earliest phases, according to researchers at the University at Buffalo and NASA’s Jet Propulsion Laboratory.

“When I look at the data, it becomes startlingly suggestive to me that this may be a window onto the primitive history of Earth,” said Tracy K. P. Gregg, Ph.D., assistant professor of geology in the UB College of Arts and Sciences.

“When we look at Io, we may be seeing what Earth looked like when it was in its earliest stages, akin to what a newborn baby looks like in the first few seconds following birth,” she added.

Gregg and Rosaly M. Lopes, Ph.D., research scientist at JPL, gave a presentation about Io’s volcano, Loki, on Tuesday (March 16, 2004) at the Lunar and Planetary Science Conference in Houston.

Scientists have been interested in Loki, considered the most powerful volcano in the solar system, because of debate over whether or not it is an active lava lake, where molten lava is in constant contact with a large reservoir of magma stored in the planet’s crust.

Using models developed to investigate temperature changes on active lava lakes on Earth, Gregg and Lopes have concluded that Loki behaves quite differently from terrestrial lava lakes.

Gregg suggests that Loki and other lava lakes on Io might be more similar volcanologically to fast-spreading mid-ocean ridges on Earth, like the Southern East Pacific Rise.

According to Gregg, plate tectonics on Earth make these features long — as in thousands of kilometers — and narrow — as in less than 10 kilometers wide. Io, on the other hand, has no plate tectonics and a similar release of heat and magma would be circular, like Loki.

“These lava lakes could be an Ionian version of mid-ocean ridges,” functioning the way these ridges do on Earth, spilling huge amounts of lava on its surface, thus generating new crust, she said.

During the most intense periods of its eruption cycle, Gregg said, Loki churns out about 1,000 square meters of lava — about the size of a soccer field — per second.

“All planets start out hot and spend their ‘lifetimes’ trying to get cold,” explained Gregg.

This effort by planets to “chill,” she explained, is an attempt to attain a similar temperature to that of outer space, which is 4 Kelvin, or minus 269 degrees Celsius.

On Earth, she explained, the shifting of the planet’s tectonic plates, which focus the eruption of volcanoes at their boundaries, function to cool down the planet’s surface.

Io never developed plate tectonics because it is stuck in an incessant orbit between Jupiter and Europa, another of the Jovian planet’s moons.

“Io just never grew up,” she said, “since it’s continually being pushed around by Jupiter and Europa.”

But, she added, Earth only developed plate tectonics after it had been in existence for perhaps 200 to 500 million years.

Gregg and Lopes analyzed data obtained by the Galileo spacecraft, which orbited Jupiter for 14 years, finally disintegrating in Jupiter’s atmosphere last fall.

The University at Buffalo is a premier research-intensive public university, the largest and most comprehensive campus in the State University of New York.

Original Source: University at Buffalo News Release

Five Visible Planets Starting Tonight

Image credit: NASA/JPL
Like a busy urban family, planets rarely get together all at once. Later this month, however, the five so-called naked-eye planets – Mercury, Venus, Mars, Jupiter and Saturn – will reunite in the night sky, giving spectators a unique chance to see Earth’s closest companions in one easy sitting.

The gathering will be visible every night for an hour after sunset, beginning around March 22 and lasting about two weeks. While other opportunities to catch a five-planet rendezvous will take place in the next few years, both at dawn and dusk, this one is not to be missed.

“This particular planetary grouping will quite possibly offer the best nighttime views until 2036,” says Dr. Myles Standish, an astronomer at NASA’s Jet Propulsion Laboratory, Pasadena, Calif.

For early risers, there will be another chance to see all five naked-eye planets together just before sunrise in December of this year and early January 2005.

Since ancient times, the naked-eye planets have intrigued and inspired onlookers all over the world. But only sporadically, usually every few years or so, do their orbits take them to the same side of the Sun. When this happens, the planets stretch across the morning or evening skies depending on which side of the Sun they reside. More rare are planetary alignments in which the five planets assemble in a very small corner of the sky.

“Every so often the five visible planets will collect on one side of the Sun,” says Standish. “Only when conditions are right, will they all be clearly visible at either dusk or dawn.”

The Details
To catch the planetary get-together, you’ll need a good view of the sky, free of buildings and bright city lights (you should still be able to see the planets through urban light pollution). The show begins around March 22 and lasts through early April, when Mercury fades from sight. The finest views will take place during the last 8 to 10 days of March.

Begin by looking to the western horizon each evening just after sunset. Seated in a row up and across the sky will be Mercury, Venus, Mars and Saturn. Saturn will lie almost directly overhead. Following the line of the planets, Jupiter will be close to the eastern horizon. Together, the planets will span about 135 degrees. About an hour after dusk, Mercury will dip below the western horizon.

The Moon will also be attending the festivities, mingling through the planets in an orderly fashion. On March 22, it will take a seat next to Mercury, and then climbing up the night sky, it will end its tour on April 1 right above mighty Jupiter, the largest planet in our solar system. As the Moon slides from planet to planet, it will grow in size from a slender crescent to a nearly full circle of white.

Note that Venus is currently brighter than usual because of where it lies in relation to Earth and the Sun.

The Moon and planets will appear to follow nearly the same path through the stars. This is because their orbits around the Sun occupy planes that are close to that of Earth’s orbit. The plane Earth moves in is called the ecliptic.

If for some reason you miss the “Fab Five,” another set of orbiting bodies will soon make a grand debut. In April and May of this year, two naked-eye comets, C/2001 Q4 and C/2002 T7, will grace the twilight skies. To spot the cosmic balls of dust and ice look to the west at dusk or dawn. A pair of binoculars will help to initially locate the comets because they may be slightly washed out by the Sun. On May 12 to 16 look out for a mini-reunion with the naked-eye planets, when comet C/2001 Q4 lines up with Venus, Mars, Saturn and Jupiter.

Original Source: NASA/JPL News Release

50th GPS Satellite Launched

Image credit: Boeing
The 50th satellite launched for the U.S. Air Force Global Positioning System (GPS), GPS IIR-11, was delivered to space today by a Boeing [NYSE: BA] Delta II rocket.

The three-stage configuration Delta II launch vehicle lifted off from Space Launch Complex 17B at Cape Canaveral Air Force Station, Fla., at 12:53 p.m. EST.

GPS IIR-11 was successfully deployed to a transfer orbit following a 68-minute flight, where it will join the 24-satellite system.

?Today?s launch is a significant milestone for the Boeing Delta team,? said Will Trafton, vice president and general manager, Boeing Expendable Launch Systems. ?Our team?s commitment to mission assurance has played a critical role in the success of the GPS program and the services it provides to the U.S. military as well as civilian users around the world.?

Boeing Delta II rockets have launched all of the Block II GPS satellites making up the current operating constellation.

The successful deployment to space of GPS satellites aboard Delta II rockets has enabled the U.S. military to utilize GPS to assist aircraft, ships, land vehicles and ground personnel using handheld devices.

GPS also provides directional guidance for the freefall flight of the Boeing-built Joint Direct Attack Munition (JDAM) smart weapon system, which has successfully been used in the war on terrorism.

GPS provides military and civilian users three-dimensional position location data in longitude, latitude and elevation as well as precise time and velocity.

The Air Force Space Command administers the GPS program, which is operated by the 50th Space Wing at Schriever Air Force Base, Colo.

The next mission for the Delta team is the launch of Gravity Probe B for NASA aboard a Delta II, scheduled for launch in April from Vandenberg Air Force Base, Calif.

A unit of The Boeing Company, Integrated Defense Systems is one of the world?s largest space and defense businesses. Headquartered in St. Louis, Boeing Integrated Defense Systems is a $27 billion business. It provides systems solutions to its global military, government and commercial customers. It is a leading provider of intelligence, surveillance and reconnaissance; the world?s largest military aircraft manufacturer; the world?s largest satellite manufacturer and a leading provider of space-based communications; the primary systems integrator for U.S. missile defense; NASA?s largest contractor; and a global leader in launch services.

Original Source: Boeing News Release

Paul Allen Funds Next Stage of SETI Project

Image credit: SETI Institute
Investor and philanthropist Paul G. Allen has committed $13.5 million to support the construction of the first and second phases of the Allen Telescope Array (the ATA-32 and ATA-206), the world’s newest multiple use radio telescope array. The ATA will eventually consist of 350 ? 6.1-meter dishes (ATA-350), when construction is completed late in the decade. The announcement was made today by Thomas Pierson, chief executive officer for the SETI Institute, a leading astrobiology institution with the mission of exploring the origin, nature and prevalence of life in the universe. The ATA is a partnership between the SETI Institute and the Radio Astronomy Laboratory of the University of California, Berkeley (RAL).

Today’s announcement follows the successful completion of a three-year research and development phase which was originally funded by an $11.5 million gift from the Allen Foundation. The R & D proved that one of the primary advantages of the array design ? its scalability ? makes it possible for the ATA to conduct scientific investigations as soon as the first 32 dishes are installed.

Pierson also announced that the ATA-32 is scheduled to begin conducting scientific investigations by the end of 2004, significantly earlier than the 350 element array can be completed.

The ATA will be a general-purpose radio telescope that will provide fundamentally new measurements and insights into the density of the very early universe, the formation of stars, the magnetic fields in the interstellar medium, and a host of other applications of deep interest to astronomers. At the same time, this 21 st Century radio telescope will also have the capability to search for possible signals from technologically advanced civilizations elsewhere in the galaxy.

“I am very excited to be supporting one of the world’s most visionary efforts to seek basic answers to some of the fundamental question about our universe and what other civilizations may exist elsewhere,” said Paul G. Allen, primary funder of the ATA. “I am a big proponent of leveraging revolutionary technology and design and applying it to important problems in science. The developments taking place with this new instrument will not only enables us to realize a lot of bang for our research and development buck, but it will also change the landscape of how telescopes will be built in the future. An instrument of this magnitude, which will result in the expansion of our understanding of how the universe was formed, and how it has evolved, and our place therein, is the reason I am the primary supporter of its development, design and construction.”

Allen’s $13.5 million funding, structured as a challenge grant, will allow construction and operation of the first phase of 32-dishes by the end of the year. It will also support construction of the second phase of 174 additional dishes (the ATA-206), which is contingent upon fulfilling the Foundations’ challenge grant, in response to which the Institute will raise $16 million in additional support.

?It is especially thrilling to see the Allen Telescope Array approach its first significant milestone,? said SETI Institute CEO Tom Pierson. ?We are grateful for the additional support from the Allen Foundation that is making this new facility ? and further discovery ? possible. Mr. Allen and his Foundation have set the bar high. Mr. Allen’s support of this worthwhile project, when matched by other supporters of radio astronomy and SETI, will quickly bring this project to fruition.?

The ATA is the result of a multi-faceted private-public partnership between the SETI Institute and the RAL. It differs in practice, appearance, and cost from traditional radio telescopes currently in use. When completed, the ATA-350 will be among the world’s largest and fastest observing instruments.

Rather than a single enormous dish or several large dishes, the ATA will be constructed using hundreds of specially produced small dishes. The telescope will incorporate innovative technologies and modern, miniaturized electronics in concert with increasingly affordable computer processing. These new technologies, combined with the ability to conduct continuous observations, will increase SETI search speed by 300 times over previous efforts and simultaneously allow astronomers to conduct complex radio astronomy projects requiring long-term observations. And the instrument will achieve these goals at one-fifth the cost of traditional radio telescopes of comparable collecting area and complexity.

In its first phase, the ATA-32 will have more antennas than any of the world’s other centimeter-wavelength radio telescopes. The individual antennas will be linked by fiber optics. The fiber, power, and air distribution systems will be installed in ten-antenna ?nodes,? an efficient way to maintain the cool operating temperature required by the equipment.

The ATA-32 will observe in the direction of the galactic anti-center to detect primordial deuterium, study dark matter in nearby dwarf galaxies, generate maps of polyatomic molecules in molecular clouds, and conduct a SETI survey of the inner galaxy.

?I am eager to begin observing on the ATA,? commented Dr. Jill C. Tarter, ATA project leader and Director of the Center for SETI Research at the Institute. ?Conducting observations 24/7 is a dream come true for any astronomer, and it is particularly exciting for the Institute’s astronomers, who have been constrained by limited time on other large centimeter wavelength telescopes. Finally, our tools are becoming commensurate with the size of our task.?

Scientists believe that radio waves, such as those commonly produced by a variety of technologies on Earth and traveling at light-speed through interstellar space, may offer the easiest way to detect evidence of a technologically sophisticated civilization elsewhere in the galaxy. With sufficient collecting area, it is possible to detect signals from a distant technology that are no more powerful than those produced on Earth today.
Dr. Leo Blitz, professor of astronomy and director of the Radio Astronomy Laboratory at UC Berkley said, “The ATA will revolutionize radio astronomy, making it possible to provide answers to the two biggest questions in astronomy: How did we get here? Are we alone?” Blitz went on to say, “The ATA’s ability to make radio images over large swaths of sky, to make measurements over an unprecedented range of radio wavelengths, and its ability to do several kinds of observations at once, provide a power and flexibility that will allow astronomers to address whole areas of astronomy that are currently inaccessible. Because of the telescope’s unique capabilities, I expect that we’ll discover things we don’t even know are out there.”

Construction of the ATA is underway at the Hat Creek Observatory, 290 miles northeast of San Francisco on a site operated by the RAL. The Hat Creek Observatory is located in an area that is ?radio quiet,’ thereby reducing the level of interfering signals from man-made sources.

Original Source: SETI Institute News Release

Rover Sees a UFO?

Image credit: NASA/JPL
Observing the sky with the green filter of it panoramic camera, the Mars Exploration Rover Spirit came across a surprise: a streak across the sky. The streak, seen in the middle of this mosaic of images taken by the navigation and panoramic cameras, was probably the brightest object in the sky at the time. Scientists theorize that the mystery line could be either a meteorite or one of seven out-of-commission spacecraft still orbiting Mars. Because the object appeared to move 4 degrees of an arc in 15 seconds it is probably not the Russian probes Mars 2, Mars 3, Mars 5, or Phobos 2; or the American probes Mariner 9 or Viking 1. That leaves Viking 2, which has a polar orbit that would fit with the north-south orientation of the streak. In addition, only Viking 1 and 2 were left in orbits that could produce motion as fast as that seen by Spirit. Said Mark Lemmon, a rover team member from Texas A&M University, Texas, “Is this the first image of a meteor on Mars, or an image of a spacecraft sent from another world during the dawn of our robotic space exploration program? We may never know, but we are still looking for clues.”

Original Source: NASA/JPL