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More than twelve billion years of cosmic history are shown in this full-color view of thousands of galaxies in various stages of morphology.

Shown in an extremely broad range of color and showcasing more than twelve billion years of cosmic history, Hubble’s recent image is a full-glory cosmic renaissance of the history of the Universe. This image provides a record of the Universe’s most exciting formative years, from the birth of stars in the early Universe all the way through the materialization of the Milky Way.

Constructed from mosaics taken with the newly installed Wide Field Camera 3 (WFC3) in fall 2009 and Hubble Space Telescope’s Advanced Camera for Surveys (ACS) taken in 2004, the final image combines a broad range of colors, from the ultraviolet, through visible light, into the near infrared. Such a detailed multi-color view of the Universe has never before been assembled at such a level of clarity, accuracy, and depth.

“It’s like taking off rose-colored glasses and seeing the Universe in a whole new light, and what we’re seeing is fantastic,” says Rogier Windhorst, a professor in the School of Earth and Space Exploration at Arizona State University, and a member of the WFC3 Science Oversight Committee. “We’re seeing stars on a galactic scale being born, we’re seeing galaxies in formation, galaxies replenished with new fuel for making stars; we’re seeing a messy Universe, a Universe in action, and we’re seeing it like astronomers have never seen it before.”

Hubble’s sharp resolution and new color versatility, accomplished by combining data from the two cameras, is allowing astronomers to sort out the various stages of galaxy assembly, from the mature spiral and elliptical galaxies in the foreground, to smaller, fainter, irregularly shaped galaxies that are in general farther away, and hence existed farther back into time. These smaller galaxies are considered the building blocks of the larger galaxies that we see today. The wide range of new colors now observed with WFC3 also allows astronomers to estimate a galaxy’s distance from Earth, and reveal information about its stellar populations.

Acquiring this image was much more time intensive than simply pointing and shooting. The data that comes off the telescope is in a raw form that requires processing. The Science Oversight Committee designed a science program to test and demonstrate the science capabilities of the WFC3, referred to as Early Release Science (ERS) data. Windhorst and students in the School of Earth and Space Exploration have been involved in the processing and analyzing the ERS data, spending the better part of July and August calibrating the data and removing background artifacts.

“Certain instrumental effects and cosmetic problems have to be taken out,” explains Seth Cohen, a postdoctoral research associate in SESE. “Some artifacts are due to cosmic rays or satellites, while others are due to the detectors themselves. You have to remove all these things before you can do the science. You don’t want to mistake the residual effects of these in your image if they are not due to something in your galaxy of interest.”

“Your eye is very good at picking out the artifacts, but you have to train a computer to do this and use software to reduce these out,” says Michael Rutkowski, a graduate student in SESE who has worked on prepping the image.

The image shows a rich tapestry of 7,500 galaxies stretching back through most of cosmic history. The closest galaxies seen in the foreground emitted their observed light only 0.9 billion years ago. The farthest galaxies, a few of the very faint red specks, are seen as they appeared more than 13 billion years ago, or roughly 650 million years after the Big Bang. This mosaic spans a slice of space that is 10 arc minutes across in its largest diameter, or about one third of the diameter of the full Moon in the sky.

The new Hubble view highlights a wide variety of stages in the galaxy assembly process. The WFC3 ultraviolet light shows the blue glow of hot, young stars in galaxies teeming with star-birth. The orange light reveals the nearly final assembly stages of massive galaxies about 8 to 10 billion years ago. The near infrared reveals the red glow of very distant galaxies --- in a few cases as far as 12--13 billion light years away --- whose light has been stretched, like a toy Slinky, from ultraviolet light to longer-wavelength infrared light due to the expansion of the Universe.

The region covers a portion of the Great Observatories Origins Deep Survey’s (GOODS) Southern field, first observed by Hubble with the ACS in 2004, and now with Hubble’s new WFC3 from Sept.-Oct. 2009.

In this ambitious use of Hubble’s observing time, the 2004 ACS exposures totaled over 100 orbits in the optical in this portion of the sky, and the new WFC3 exposures total 104 orbits in the ultraviolet and near-infrared. The image was made from a mosaic of 2x4 WFC3 ultraviolet pointings, and 2x5 WFC3 near-infrared pointings. In just two orbits per pointing, the WFC3 peered deeper into the Universe than comparable near-infrared observations from ground-based telescopes. This set of unique new Hubble observations reveals galaxies to about 27th magnitude in brightness over a factor of 10 in wavelength.

“Having this broad spectrum wavelength coverage allows us to do many different things that we couldn’t do before without having deep observations at all these wavelengths at the Hubble resolution,” says Cohen.

Astronomers are using this multi-color panorama to trace many details of galaxy formation over cosmic time: the star-formation rate in galaxies, the rate of mergers among galaxies, and the abundance of weak active galactic nuclei, along with many other measurable quantities.

Rutkowski is most excited about the panchromatic nature, particularly the UV capabilities since UV astronomy can’t be done from the ground.

“My interest is in elliptical galaxies known as “red and dead galaxies.” We believed that there wasn’t much going on by way of current star formation in these galaxies, but as the UV becomes more accessible, there are a lot of red and dead galaxies that are actually quite blue. This image suggests that they’re neither as red nor as dead as we originally thought.”

NASA’s MESSENGER mission team and cartographic experts from the U. S. Geological Survey have created a critical tool for planning the first orbital observations of the planet Mercury – a global mosaic of the planet that will help scientists pinpoint craters, faults, and other features for observation. The map was created from images taken during the MESSENGER spacecraft’s three flybys of the planet and those of Mariner 10 in the 1970s. A presentation on the new global mosaic is being given today at the Fall Meeting of the American Geophysical Union in San Francisco.

The MESSENGER spacecraft completed its third and final flyby of Mercury on September 29, concluding its reconnaissance of the innermost planet. The MESSENGER team has been busily preparing for the yearlong orbital phase of the mission, beginning in March 2011, and the near-global mosaic of Mercury from MESSENGER and Mariner 10 images is key to those plans.

“The production of this global mosaic represents a major milestone for everyone on the MESSENGER imaging team,” says MESSENGER Principal Investigator Sean Solomon of the Carnegie Institution of Washington. “Beyond its extremely important use as a planning tool, this global map signifies that MESSENGER is no longer a flyby mission but instead will soon become an in-depth, non-stop global observatory of the Solar System’s innermost planet.”

“The process of making a mosaic may seem relatively straightforward — simple software can stitch together panoramas from multiple images. However, the challenging part has been to make cartographically accurate maps from a series of images with varying resolution (from about 100 to 900 meters per pixel) and lighting conditions (from noontime high Sun to dawn and dusk) taken from a spacecraft traveling at speeds greater than 2 kilometers per second (2,237 miles per hour),” says Mark Robinson, a professor in the School of Earth and Space Exploration at Arizona State University and a member of the MESSENGER Science Team.

Small uncertainties in camera pointing and changes in image scale can introduce small errors between frames, Robinson says. “And with lots of images, small errors add up and lead to large mismatches between features in the final mosaic. By picking control points — the same features in two or more images — the camera pointing can be adjusted until the image boundaries match.” This operation is known as a bundle-block adjustment and requires highly specialized software.

Cartographic experts at the USGS Astrogeology Science Center in Flagstaff, Ariz., picked the control points to solve the bundle-block adjustment to construct the final mosaic using the Integrated Software for Imagers and Spectrometers (ISIS). For the MESSENGER mosaic, 5,301 control points were selected, and each control point on average was found in more than three images (18,834 measurements) from a total of 917 images. Scientists at ASU and the Johns Hopkins University Applied Physics Laboratory (APL) were also instrumental in making the mosaic possible.

“This mosaic represents the best geodetic map of Mercury’s surface. We want to provide the most accurate map for planning imaging sequences once MESSENGER achieves orbit around Mercury,” says Kris Becker of the USGS. “As the systematic mapping of Mercury’s surface progresses, we will continually add new images to the control point network, thus refining the map,” he says. “It has already provided us with a start in the process of naming newly identified features on the surface.”

In the final bundle-block adjustment the average error was about two-tenths of a pixel or only about 100 meters — which is an excellent match from image-to-image. The biggest remaining issue is the absolute control of features on the surface. For instance, if the north pole is not precisely at the spin axis you could have a mosaic in which all the seams overlapped perfectly, but the whole mosaic could slide around like the skin of an orange that somehow became detached from the interior fruit.

Much work was done with the Mariner 10 images collected in 1974 and 1975 to make an absolute control network even though only 45% of the planet was seen at the time. The longitude system for Mercury is tied to a small crater named Hun Kal (the number twenty in an ancient Mayan language, because the crater is centered at 20°W). For now, MESSENGER data are tied to the earlier Mariner 10 control network.

Absolute positional errors in the new mosaic are about two kilometers, according to the MESSENGER team. Once the MESSENGER spacecraft orbits Mercury, much progress will be made refining the relative and absolute control of the MESSENGER (and Mariner 10) images, and the entire planet will be imaged at even higher resolution. The global mosaic is available for download on the USGS Map-a-Planet web site, http://www.mapaplanet.org.

MESSENGER (MErcury Surface, Space ENvironment, GEochemistry, and Ranging) is a NASA-sponsored scientific investigation of the planet Mercury and the first space mission designed to orbit the planet closest to the Sun. The MESSENGER spacecraft launched on August 3, 2004, and after flybys of Earth, Venus, and Mercury will start a yearlong study of its target planet in March 2011.

Prepared jointly by ASU, USGS, JHU-APL
 

That possibility is raised in a recent paper in the scientific journal Icarus by scientist Diedrich Möhlmann of the German Aerospace Center in Berlin, according to a report published Dec. 2 by NewScientist.com.

If sunlight can enter deposits of ice near the Martian surface, embedded particles of dirt or dust could grow warm by a kind of greenhouse effect, and form tiny pockets of meltwater around them. Sealed in by overlying ice, the water would be protected from evaporating. Such an environment could preserve liquid water near the Martian surface and provide a possible habitat for life.

When New Scientist writer David Shiga asked ASU Mars scientist and professor Philip Christensen about the idea, he replied, "If I was going to search for life on Mars I would certainly include landing and looking at some of these potential snow deposits."

The School of Earth and Space Exploration hosted a symposium “Living with the Planet” Nov. 13 that featured the premiere screening of the documentary film “Mud Max: Investigative Documentary - Sidoardjo Mud Volcano Disaster.” The event included a panel discussion with earth scientists from leading European and American institutions, which concluded that the cause of the Sidoardjo mud volcano disaster (also known as LUSI) is still inconclusive.

No disaster in recent history has received as much attention nor created as much controversy as that of LUSI, the world’s fastest growing mud volcano in Indonesia that suddenly erupted on May 29, 2006. Dubbed LUSI as a compendium of the Indonesian word for mud (lumpur) and the East Java town near which LUSI was born (Sidoarjo), the phenomenon has been a unique disaster. The hot mud, which first began spewing from the earth following a powerful earthquake and nearby exploration drilling, is still pouring forth at the rate of up to 150,000 cubic meters per day. Some 40,000 residents living near the eruption have lost their homes, belongings and, in some cases livelihoods and lives. Whole villages have been inundated with mud, infrastructures destroyed and reputations ruined.

International experts have been divided over the cause of the mud eruption. The early point of views favored the theory that the nearby drilling activity may have triggered the eruption, but others, after having time for considerable scientific investigation, support the idea that seismic activity linked to an earthquake just two days before the mud eruption began could have been the likely cause.

While conducting research in Indonesia, Associate Professor Amanda Clarke was interviewed by the film crew creating the documentary film ‘Mud Max.’ The project was produced over a 27-month period by the British company Immodicus in conjunction with the School of Earth and Space Exploration and involved researchers, geologists, drilling experts and scientists whom explore the facts of the tragic, on-going disaster including the scientific, economic, humanitarian and political issues that have made LUSI the talk of the geophysical world. The film aims to highlight the facts and views from every side, but leaves the decision to the viewer as to what caused the mud volcano eruption.

Rather than pointing fingers and dwelling on the causes of the eruption, the Living with the Planet panelists emphasized the importance of seeking out solutions and using LUSI to learn from.

Panel member Jonathan Fink, professor in the School of Earth and Space Exploration and director of the Center for Sustainability Science Applications, pointed out that volcanology is a relatively young science that requires observations of active eruptions to advance knowledge.

“Mud volcanism of the scale of LUSI has rarely if ever been seen before, so volcanologists may not be able to answer all of the questions that policy makers and the public want to know,” explains Fink. “Each eruption teaches us something new, so LUSI may help scientists interpret future mud events.”

Adriano Mazzini, a researcher at the Physics of Geological Processes Centre of Excellence (University of Oslo), whose research has focused on mud volcanoes, has conducted extensive research on LUSI during his three visits.

“Our results support a scenario where the strike-slip movement of the Watukosek fault triggered the Lusi eruption and synchronous seep activity witnessed at other mud volcanoes along the same fault,” says Mazzini. “The possibility that drilling contributed to trigger the eruption cannot be excluded. However, so far, no univocal data support the drilling hypothesis, and a blow-out scenario can neither explain the dramatic changes that affected the plumbing system of numerous seep systems on Java after the May 27 earthquake.”

Preparing for and reacting quickly to natural disasters such as LUSI requires both deep knowledge of the broader Earth system context and careful monitoring of biological, chemical, and physical processes.

“The development of effective environmental monitoring systems has not progressed very far as yet, and Indonesia - with its complex geology and high risk of natural hazards - would be an excellent place to develop and test state-of-the-art monitoring technologies,” says Kip Hodges, director of the School of Earth and Space Exploration. “The School of Earth and Space Exploration at ASU is establishing itself as one of the premier centers for such technology development. We are very excited to explore opportunities to work with our friends in Indonesia to develop world-class hazard monitoring systems for deployment in their country.”

The school sees an important aspect of such collaboration as being a cooperative educational program that would provide opportunities for bright young Indonesian students to receive training at ASU in science and engineering, such that they can return to Indonesia and play leadership roles in developing a strong intellectual foundation for Indonesia in Earth system science and engineering.

According to Clarke and other panel members, the region around LUSI is very complex geologically, making prediction of future mud activity difficult at best.

“Real-time and/or continuous monitoring of several key geophysical, geochemical and volcanological parameters will provide data to help understand the phenomenon,” she says. “This type of campaign, coupled with context gained from detailed study of the area's geologic past, may help scientists predict LUSI's future.”

(Nikki Staab)