First Pictures from Hubble’s New Camera

Image credit: Hubble

NASA provided the first pictures today from the newly refurbished Hubble Space Telescope. Among the four new images unveiled to the public today included colliding galaxies, and several nebulas. The Advanced Cameral for Surveys was installed by the crew of the space shuttle Atlantis just a few months ago, and seems to be working well. Operators expect it will be ten times more efficient than the observatory’s previous camera – so far, so good.

“Remarkable, breathtaking” are words jubilant astronomers are using to describe the first four views of the universe taken by the Hubble Space Telescope’s new Advanced Camera for Surveys, released by NASA today.

The new camera was installed on Hubble by astronauts during a shuttle mission last March, the fourth Hubble Space Telescope servicing mission. During five of the most challenging spacewalks ever attempted, the crew successfully upgraded the orbiting telescope with the new camera, a new power unit, new solar arrays and an experimental cooling unit for an infrared camera. Hubble managers say the orbiting telescope has been operating superbly since the servicing mission.

“Today marks the beginning of a new era of exploration with Hubble,” said Dr. Ed Weiler, Associate Administrator for Space Science at NASA Headquarters, Washington. “Our team of scientists and engineers on the ground and the astronauts in space once again did the impossible. After 12 years in space, Hubble not only was given a major overhaul, its new camera has already shown us that, even after 12 years of great science and astounding images, we haven’t seen anything yet.”

Among the suite of four “suitable-for-framing” Advanced Camera for Surveys (ACS) science-demonstration pictures released today is a stunning view of a colliding galaxy, dubbed the “Tadpole,” located 420 million light-years away. Unlike textbook images of stately galaxies, the “Tadpole” ? with a long tail of stars ? captures the essence of a dynamic, restless and violent universe, looking like a runaway pinwheel firework.

“The ACS is opening a wide new window onto the universe. These are among the best images of the distant universe humans have ever seen,” said astronomer Holland Ford of Johns Hopkins University in Baltimore, lead scientist in the camera’s seven-year development.

The camera’s tenfold increase in efficiency will open up much anticipated new capability for discovery. “ACS will allow us to push back the frontier of the early universe. We will be able to enter the ‘twilight zone’ period when galaxies were just beginning to form out of the blackness following the cooling of the universe from the big bang,” said Ford.

The ACS is a camera of superlatives. It is expected to surpass the sensitivity of the largest ground-based telescope to eventually see the very faintest objects ever recorded. The camera delivers a panoramic crispness comparable to that of a wide-screen movie, containing 16 million picture elements (megapixels) per image. By comparison, digital photos from typical consumer cameras are 2 to 4 megapixels.

The ACS image of the Tadpole illustrates the dramatic gains over the Wide Field Planetary Camera 2 resulting from doubling the area and resolution, and demonstrates a five- fold improvement in sensitivity. An unexpected bonus is the enormous number of galaxies in the new Hubble image beyond the Tadpole galaxy, giving it an appearance like the galaxy- filled Hubble Deep Field (HDF) image, taken in 1995. However, the ACS picture was taken in one-twelfth the time it took for the original HDF. Like the Hubble Deep Field, the ACS galaxies contain myriad shapes that are snapshots of galaxies throughout the universe’s 13 billion-year evolution. The ACS images are so sharp astronomers can identify “building blocks” of galaxies, colliding galaxies and extremely distant galaxies in the field ? an exquisite sampler of galaxies.

“The ACS will let us obtain the deepest image of the universe for the foreseeable future,” added astronomer Garth Illingworth of the University of California, Lick Observatory, Santa Cruz, the deputy leader for the camera team.

The other pictures include a stunning collision between two spiral galaxies, dubbed “the Mice,” that presage what might happen to our own Milky Way several billion years in the future when it collides with the neighboring galaxy in the constellation Andromeda. Computer simulations, made by Joshua Barnes of the University of Hawaii and John Hibbard of the National Radio Astronomy Observatory, show that we are seeing the collision of the Mice approximately 160 million years after their closest encounter. Running the simulations forward in time shows that the two galaxies will eventually merge. A similar fate may await the Milky Way and the Andromeda galaxy.

Looking closer to home, ACS imaged the “Cone Nebula,” a craggy-looking mountaintop of cold gas and dust that is a cousin to Hubble’s iconic “pillars of creation” in the Eagle Nebula, photographed in 1995.

Peering into a celestial maternity ward called the M17 Swan Nebula, the ACS revealed a watercolor fantasy-world tapestry of vivid colors and glowing ridges of gas. Embedded in this crucible of star creation are embryonic planetary systems.

In addition to the ACS, spacewalking astronauts installed a new high-tech mechanical “refrigerator” on Hubble during the servicing mission. This “cryocooler” has successfully pumped most of the heat out of the interior of the Near Infrared Camera and Multi-Object Spectrometer (NICMOS), achieving and maintaining to within a few hundredths of one degree the target temperature for neon gas passing through the instrument of 70 degrees Kelvin (minus 203 degrees Centigrade or minus 333 degrees Fahrenheit).

Engineers are now in the process of checking out the operation of the resuscitated NICMOS instrument. By early June, scientists expect to release the first astronomical images taken with the NICMOS since 1998, when it was still being cooled by a rapidly depleting block of solid nitrogen ice.

The new rigid solar arrays, working with the new Power Control Unit, are generating 27 percent more electrical power than the previous arrays. This doubles the electrical power that can be allocated to the scientific instruments on Hubble. The new reaction wheel is operating normally. Nearly a month ago, the Space Telescope Imaging Spectrograph and the Wide Field and Planetary Camera 2 resumed science observations.

“This servicing mission has turned out to be an extraordinary success,” said Preston Burch, Hubble Project Manager at NASA’s Goddard Space Flight Center in Greenbelt, Md. “It was the most difficult and complicated Hubble servicing mission attempted to date and our observatory came through it with flying colors.”

Soyuz Docks with Space Station

South African space tourist Mark Shuttleworth and his two crewmates arrived at the International Space Station when their Soyuz capsule docked on Saturday. The three visitors entered and were greeted with big hugs by the station’s residents. A few hours later Shuttleworth was congratulated by South African President Thabo Mbeki for his achievement of becoming the first African in space.

Soyuz Launches with Space Tourist

Space tourist Mark Shuttleworth is finally on his way to visit the International Space Station. Shuttleworth and his companions, Yuri Gidzenko and Roberto Vittori, lifted off from the Baikonur cosmodrome in Kazakhstan at 0626 GMT (2:26 am EDT) on board a Russian Soyuz rocket. The Soyuz will dock with the International Space Station on Saturday. This team will visit the station for a week, and then return to Earth in the replacement Soyuz currently docked.

Book Review: Bad Astronomy by Phil Plait

Astronomer Phil Plait has found a great niche for himself – debunking bad science, specifically Bad Astronomy. He’s been at it on the web for years, and it came as no surprise to me when I found out there was a book deal in the works.

Astronomer Phil Plait has found a great niche for himself – debunking bad science, specifically Bad Astronomy. He’s been at it on the web for years, and it came as no surprise to me when I found out there was a book deal in the works.

Bad Astronomy: Misconceptions and Misuses Revealed, from Astrology to the Moon Landing “Hoax” is exactly what it sounds like. For 260ish pages Phil takes a look at many of the common misconceptions that have plagued astronomy for years.

The first half of the book is interesting reading, but it’s more of a science book. Phil looks at many of the commonly misunderstood concepts in astronomy and sets the record straight. I’d like to think I know a little about astronomy, so I was pretty surprised to learn I was misinformed about many aspects of the basics: tides, meteors, gravity.

It’s in the second half of the book where Plait really hits his stride as he examines some of the “bad astronomy” hatched more recently: Apollo moon landing hoaxes, UFOs etc. Because the culprits are still spinning out the bad science, Phil firmly debunks their “theories”. I especially enjoyed the Top Ten Examples of Bad Astronomy in Hollywood.

If I had a complaint, it’s that Phil spends a little too much time explaining how to balance an egg in any season (a whole chapter!, but I guess he was trying to make a point). Seriously, though, it’s a great book, not Bad Astronomy at all.

Click here to find out more from Amazon.com.

Fraser Cain
Publisher, Universe Today

When Galaxies Collide

Image credit: Chandra

A new image taken by the Chandra X-Ray Observatory has provided one of the best views of two galaxies similar to our own Milky Way in the midst of a collision. All galaxies, including our own, have gone through this kind of merger in the past, so this image helps astronomers understand how the Universe came to look like it does today. The galaxies began their slow collision 10-million years ago and have already created regions of intense star formation and may eventually create a supermassive black hole.

NASA’s Chandra X-ray Observatory has provided the best X-ray image yet of two Milky Way-like galaxies in the midst of a head-on collision. Since all galaxies – including our own – may have undergone mergers, this provides insight into how the universe came to look as it does today.

Astronomers believe the mega-merger in the galaxy known as Arp 220 triggered the formation of huge numbers of new stars, sent shock waves rumbling through intergalactic space, and could possibly lead to the formation of a supermassive black hole in the center of the new conglomerate galaxy. The Chandra data also suggest that merger of these two galaxies began only 10 million years ago, a short time in astronomical terms.

“The Chandra observations show that things really get messed up when two galaxies run into each other at full speed,” said David Clements of the Imperial College, London, one of the team members involved in the study. “The event affects everything from the formation of massive black holes to the dispersal of heavy elements into the universe.”

Arp 220 is considered to be a prototype for understanding what conditions were like in the early universe, when massive galaxies and supermassive black holes were presumably formed by numerous galaxy collisions. At a relatively nearby distance of about 250 million light years, Arp 220 is the closest example of an “ultra-luminous” galaxy, one that gives off a trillion times as much radiation as our Sun.

The Chandra image shows a bright central region at the waist of a glowing, hour-glass-shaped cloud of multimillion-degree gas. Rushing out of the galaxy at hundreds of thousands of miles per hour, the super-heated as forms a “superwind,” thought to be due to explosive activity generated by the formation of hundreds of millions of new stars.

Farther out, spanning a distance of 75,000 light years, are giant lobes of hot gas that could be galactic remnants flung into intergalactic space by the early impact of the collision. Whether the lobes will continue to expand into space or fall back into Arp 220 is unknown.

The center of Arp 220 is of particular interest. Chandra observations allowed astronomers to pinpoint an X-ray source at the exact location of the nucleus of one of the pre-merger galaxies. Another fainter X-ray source nearby may coincide with the nucleus of the other galaxy remnant. The X-ray power output of these point-like sources is greater than expected for stellar black holes accreting from companion stars. The authors suggest that these sources could be due to supermassive black holes at the centers of the merging galaxies.

These two remnant sources are relatively weak, and provide strong evidence to support the theory that the extraordinary luminosity of Arp 220 – about a hundred times that of our Milky Way galaxy – is due to the rapid rate of star formation and not to an active, supermassive black hole in the center.

However, in a few hundred million years, this balance of power may change. The two massive black holes could merge to produce a central supermassive black hole. This new arrangement could cause much more gas to fall into the central black hole, creating a power source equal to or greater than that due to star formation.

“The unusual concentration of X-ray sources in the very center of Arp 220 suggests that we could be observing the early stages of the creation of a supermassive black hole and the eventual rise to power of an active galactic nucleus,” said Jonathan McDowell of the Harvard-Smithsonian Center for Astrophysics, Cambridge, MA, another member of the team studying Arp 220.

Clements and McDowell were joined on this research by an international group of researchers from the United States, United Kingdom and Spain. Chandra observed Arp 220 on June 24, 2000, for approximately 56,000 seconds using the Advanced CCD Imaging Spectrometer (ACIS) instrument.

ACIS was developed for NASA by Pennsylvania State University, University Park, PA, and the Massachusetts Institute of Technology, Cambridge, MA. NASA’s Marshall Space Flight Center in Huntsville, Ala., manages the Chandra program, and TRW, Inc., Redondo Beach, Calif., is the prime contractor. The Smithsonian’s Chandra X-ray Center controls science and flight operations from Cambridge, Mass.

ESA Plans Another Look at the Moon

The European Space Agency is working on a new spacecraft that will visit the Moon and map its surface in great detail. The SMART-1, due for launch in 2003 will arrive at the Moon and begin a detailed analysis of the surface from different angles, in regular light, infrared and X-ray and then produce a three-dimensional map. Smart-1 will visit the dark southern pole of the Moon for the first time and help investigate areas which have never been touched by the Sun.

NASA Approves Shuttleworth’s Visit

NASA has given its blessing for millionaire space tourist Mark Shuttleworth to visit the International Space Station. The previous paying visitor, Dennis Tito, was permitted into the station, but required constant supervision. Shuttleworth will lift off Thursday on board a Russian Soyuz rocket from the Baikonur cosmodrome in Kazakhstan and dock with the station Saturday.

Hubble Helps with New Measurement for Universe’s Age

Image credit: Hubble

Thanks to the Hubble Space Telescope, astronomers are using ancient stars in the Milky Way to come up with an independent estimate about the age of the Universe. In the past, astronomers have calculated this age using its rate of expansion, and pegged it between 13-14 billion years old. Under this new method, the astronomers targeted ancient white dwarf stars which cool down at a very predictable rate. These stars were formed near the beginning of the Universe, and the astronomers were able to estimate that they are between 12-13 billion years old. Close enough.

Pushing the limits of its powerful vision, NASA’s Hubble Space Telescope has uncovered the oldest burned-out stars in our Milky Way Galaxy. These extremely old, dim “clockwork stars” provide a completely independent reading on the age of the universe without relying on measurements of the expansion of the universe.

The ancient white dwarf stars, as seen by Hubble, turn out to be 12 to 13 billion years old. Because earlier Hubble observations show that the first stars formed less than 1 billion years after the universe’s birth in the big bang, finding the oldest stars puts astronomers well within arm’s reach of calculating the absolute age of the universe.

Though previous Hubble research sets the age of the universe at 13 to 14 billion years based on the rate of expansion of space, the universe’s birthday is such a fundamental and profound value that astronomers have long sought other age-dating techniques to cross-check their conclusions. “This new observation short-circuits getting to the age question, and offers a completely independent way of pinning down that value,” says Harvey Richer of the University of British Columbia, Canada.

The new age-dating observations were done by Richer and colleagues by using Hubble to go hunting for elusive ancient stars hidden inside a globular star cluster located 5,600 light-years away in the constellation Scorpius. The results are to be published in the Astrophysical Journal Letters.

Conceptually, the new age-dating observation is as elegantly simple as estimating how long ago a campfire was burning by measuring the temperature of the smoldering coals. For Hubble, the “coals” are white dwarf stars, the burned out remnants of the earliest stars that formed in our galaxy.

Hot, dense spheres of carbon “ash” left behind by the long-dead star’s nuclear furnace, white dwarfs cool down at a predictable rate ? the older the dwarf, the cooler it is, making it a perfect “clock” that has been ticking for almost as long as the universe has existed.

This approach has been recognized as more reliable than age-dating the oldest stars still burning by nuclear fusion, which relies on complex models and calculations about how a star burns its nuclear fuel and ages. White dwarfs are easier to age-date because they are simply cooling, but the trick has always been finding the dimmest and hence longest-running “clocks.”

As white dwarfs cool they grow fainter, and this required that Hubble take many snapshots of the ancient globular star cluster M4. The observations amounted to nearly eight days of exposure time over a 67-day period. This allowed for even fainter dwarfs to become visible, until at last the coolest ? and oldest ? dwarfs were seen. These stars are so feeble (at 30th magnitude ? which is considerably fainter than originally anticipated for any Hubble telescope imaging with the original cameras), they are less than one-billionth the apparent brightness of the faintest stars that can be seen by the naked eye.

Globular clusters are the first pioneer settlers of the Milky Way. Many coalesced to build the hub of our galaxy and formed billions of years before the appearance of the Milky Way’s magnificent pinwheel disk (as further confirmed by Richer’s observations). Today 150 globular clusters survive in the galactic halo. The globular cluster M4 was selected because it is the nearest to Earth, so the intrinsically feeblest white dwarfs are still apparently bright enough to be picked out by Hubble.

In 1928, Edwin Hubble’s measurements of galaxies made him realize that the universe was uniformly expanding, which meant the universe had a finite age that could be estimated by mathematically “running the expansion backward.” Edwin Hubble first estimated the universe was only 2 billion years old. Uncertainties over the true expansion rate led to a spirited debate in the late 1970s, with estimates ranging from 8 billion to 18 billion years. Estimates of the ages of the oldest normal “main-sequence” stars were at odds with the lower value, since stars could not be older than the universe itself.

In 1997 Hubble astronomers broke this impasse by triumphantly announcing a reliable age for the universe, calculated from a very precise measurement of the expansion rate. The picture soon got more complicated when astronomers using Hubble and ground-based observatories discovered the universe was not expanding at a constant rate, but accelerating due to an unknown repulsive force termed “dark energy.” When dark energy is factored into the universe’s expansion history, astronomers arrive at an age for the universe of 13-14 billion years. This age is now independently verified by the ages of the “clockwork” white dwarfs measured by Hubble.

Original Source: Hubble News Release

Survey Confirms Dark Energy Theories

Image credit: Hubble

Recent evidence seems to indicate that the expansion of the Universe is actually accelerating – some kind of “dark energy” is pushing it apart. And a new redshift survey of galactic clusters seems to support this. Astronomers using data gathered by the Chandra X-Ray Observatory have determined that there is insufficient matter (both regular and dark matter) in various galactic clusters to account for their shape and position, so something else must be having an effect.

The universe appears to be permeated with an invisible force ? dark energy ? that is pushing it apart faster and faster. By conducting redshift surveys of galaxy clusters, astronomers hope to learn more about this mysterious force, and about the structure and geometry of the universe.

“Galaxy clusters consist of thousands of galaxies gravitationally bound into huge structures,” said Joseph Mohr, a professor of astronomy at the University of Illinois. “Because of the expansion of the universe, the clusters appear denser at larger redshifts, when the universe was younger and denser.”

Galaxy cluster surveys that probe the high-redshift universe can potentially provide a wealth of information about the amount and nature of both dark matter and dark energy, said Mohr, who will present the results of an ongoing study of galaxy clusters at a meeting of the American Physical Society, to be held in Albuquerque, N.M., April 20-23.

“Till now, galaxy clusters have only been used to study the dark matter component of the universe,” Mohr said. “We would measure the total mass in a galaxy cluster, and then determine the fraction of mass that was ordinary, baryonic matter.”

Those measurements have shown there is insufficient baryonic and dark matter to account for the geometry of the universe. Astronomers now believe the universe is expanding at ever-increasing speed, and is dominated by a mysterious dark energy that must be doing the pushing.

“The next step is to try to figure out some of the specifics of the dark energy, such as its equation of state,” Mohr said. “By mapping the redshift distribution of galaxy clusters, we should be able to measure the equation of state of dark energy, which would provide some important clues to what it is and how it came to be.”

Mohr is using data collected by NASA’s Chandra X-ray Observatory to study scaling relations ? such as the relationship between mass and luminosity or size ? of galaxy clusters and how they change with redshift. “These scaling relations are expected to evolve with redshift, reflecting the increasing density of the universe at earlier times,” Mohr said.

In particular, Mohr ? in collaboration with John Carlstrom at the University of Chicago and scientists at the University of California and Harvard Smithsonian Center for Astrophysics ? is studying the effect that hot electrons within galaxy clusters have on the cosmic microwave background, the afterglow of the big bang.

Galaxy clusters are filled with dark matter, galaxies and hot gas. Electrons in the gas scatter off the protons and produce X-rays. The emission of X-rays diminishes with higher redshift, because of the larger distances involved.

“There also is a tendency for the electrons to give some of their energy to the photons of the cosmic microwave background, which causes the blackbody spectrum to shift slightly,” Mohr said. “The resulting distortion ? called the Sunyaev-Zeldovich effect ? appears as a cold spot on the cosmic microwave background at certain frequencies. Because this is a distortion in the spectrum, however, it doesn’t dim with distance like X-rays.”

By comparing the X-ray emission and the Sunyaev-Zeldovich effect, Mohr can study even faint, high-redshift galaxy clusters that are currently inaccessible by other means. Such measurements, correlating galaxy cluster redshift distribution, structure and spatial distribution, should determine the equation of state of dark energy and, therefore, help define the essence of dark energy.

“Within the context of our standard structure formation scenario, galaxy surveys provide measurements of the geometry of the universe and the nature of the dark matter and dark energy,” Mohr said. “But, to properly interpret these surveys, we must first understand how the structure of galaxy clusters are changing as we look backward in time.”

Original Source: UIUC News Release

Star Formation Exposed

Image credit: Chandra

A new photograph taken by the Chandra X-Ray Observatory shows a close up view of the dynamics of star formation in the Tarantula Nebula (aka 30 Doradus). This region, located 160,000 light years away is one of the most active star forming regions in our local group of galaxies and provides a lot of clues to astronomers. In this region, astronomers have identified at least 11 extremely massive stars with ages of only 2 million years with many more young stars packed together so tightly individual stars can’t be resolved.

The Chandra image of the Tarantula Nebula gives scientists a close-up view of the drama of star formation and evolution. The Tarantula, also known as 30 Doradus, is in one of the most active star-forming regions in our Local Group of galaxies. Massive stars are producing intense radiation and searing winds of multimillion-degree gas that carve out gigantic super-bubbles in the surrounding gas. Other massive stars have raced through their evolution and exploded catastrophically as supernovas, leaving behind pulsars and expanding remnants that trigger the collapse of giant clouds of dust and gas to form new generations of stars.

30 Doradus is located about 180,000 light years from Earth in the Large Magellanic Cloud, a satellite galaxy of our Milky Way Galaxy. It allows astronomers to study the details of starbursts – episodes of extremely prolific star formation that play an important role in the evolution of galaxies.

At least 11 extremely massive stars with ages of about 2 million years are detected in the bright star cluster in the center of the primary image (left panel). This crowded region contains many more stars whose X-ray emission is unresolved. The brightest source in this region known as Melnick 34, a 130 solar-mass star located slightly to the lower left of center. On the lower right of this panel is the supernova remnant N157B, with its central pulsar.

Two off-axis ACIS-S chips (right panel) were used to expand the field of view. They show SNR N157C, possibly a large shell-like supernova remnant or a wind-blown bubble created by OB stars. Supernova 1987A is also visible just above and to the right of the Honeycomb Nebula at the bottom center.

In the image, lower energy X-rays appear red, medium energy green and high-energy are blue.

Original Source: Chandra News Release