New research may explain mysterious dents in Earth”s gravitational field

May 10, 2010 By Leave a Comment

London, May 10 (ANI): Scientists have made an advance in understanding the mysterious dents in our planet”s gravitational field.

On sailing towards the centre of the Indian Ocean and a loss in one”s weight is observed because here the Earth”s gravitational field is weaker.

Similar dents in field strength can be observed in the north-east Pacific Ocean and the Ross Sea.

These weaknesses are believed to be a product of “slab graveyards” – ancient pieces of crust and sediment that were pushed down into the Earth when plates collided and are now falling through the mantle.

Since the slabs are denser than the surrounding mantle, they tend to have a stronger gravitational pull.

But when they fall their effect on the gravitational field at the Earth”s surface lessens.

However, surrounding these areas are even weaker, unexplained dents in the field.

According to Sonja Spasojevic from the California Institute of Technology in Pasadena and colleagues, this could be because the movement of the slabs through the mantle forces plumes of less dense material to rise towards the surface.

They believe the distribution of the unexplained weak spots simply reflects the pattern of these plumes.

“The new explanation is plausible but there are other possibilities too,” New Scientist quoted Norm Sleep a geophysicist at Stanford University in California, as saying.

The study has appeared in the journal Nature Geoscience. (ANI)

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Earth’s weak magnetic field helped Sun to steal water from planet’s early atmosphere

March 6, 2010 By Leave a Comment

Washington, March 5 (ANI): Scientists have discovered that the Earth’s magnetic field 3.5 billion years ago was only half as strong as it is today, and that this weakness, coupled with a strong wind of energetic particles from the young Sun, likely stripped water from the early Earth’s atmosphere.

The findings, by researchers at the University of Rochester, US, suggest that the magnetopause—the boundary where the Earth’s magnetic field successfully deflects the Sun’s incoming solar wind—was only half the distance from Earth it is today.

“With a weak magnetosphere and a rapid-rotating young Sun, the Earth was likely receiving as many solar protons on an average day as we get today during a severe solar storm,” said John Tarduno, a geophysicist at the University of Rochester and lead author of the study.

“That means the particles streaming out of the Sun were much more likely to reach Earth. It’s very likely the solar wind was removing volatile molecules, like hydrogen, from the atmosphere at a much greater rate than we’re losing them today,” he said.

According to Tarduno, the loss of hydrogen implies a loss of water as well, meaning there may be much less water on Earth today than in its infancy.

To find the strength of the ancient magnetic field, Tarduno and his colleagues from the University of KwaZulu-Natal visited sites in Africa that were known to contain rocks in excess of 3 billion years of age.

Tarduno picked out the best preserved grains of feldspar and quartz out of 3.5 billion-year-old dacite outcroppings in South Africa.

Once he isolated the ideal crystals, Tarduno used a device called a superconducting quantum interface device, or SQUID magnetometer.

Using the new magnetometer, the researchers were able to confirm that the 3.5 billion-year-old silicate crystals had recorded a field much too strong to be induced by the solar wind-atmosphere interaction, and so must have been generated by Earth’s core.

“We needed to understand how much solar wind that magnetic field was deflecting because that would tell us what was probably happening to Earth’s atmosphere,” said Tarduno.

The solar wind can strip away a planet’s atmosphere and bathe its surface in lethal radiation.

To discover what kind of solar wind the Earth had to contend with, Tarduno employed the help of Eric Mamajek, assistant professor of physics and astronomy at the University of Rochester.

“We estimate the solar wind at that time was a couple of orders of magnitude stronger,” he said.

The smaller magnetopause allowed the solar wind to strip away more water vapor from the early Earth. (ANI)

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Scientists create first complete seismic image of crust beneath Himalayan Mountains

September 12, 2009 By Leave a Comment

Washington, September 12 (ANI): An international team of researchers has created the most complete seismic image of the Earth’s crust and upper mantle beneath the rugged Himalaya Mountains, in the process discovering some unusual geologic features that may explain how the region has evolved.

Their findings help explain the formation of the world’s largest mountain range, which is still growing.

The researchers discovered that as the Indian and Eurasian tectonic plates collide, the Indian lower crust slides under the Tibetan crust, while the upper mantle peels away from the crust and drops down in a diffuse manner.

“The building of Tibet is not a simple process,” said John Nabelek, an Oregon State University geophysicist and lead author on the Science study.

“In part, the mountain building is similar to pushing dirt with a bulldozer except in this case, the Indian sediments pile up into a wedge that is the lesser Himalayan mountains,” he added.

“However, an important component of the mass transfer from the upper crust of India to the Himalayas also occurs at depth through viscous processes, while the lower crust continues sliding intact farther north under the Tibet plateau,” Nabelek further added.

The findings are important because there has been clear scientific consensus on the boundaries and processes for that region’s tectonic plates.

In fact, the piecemeal images gathered by previous research have led to a series of conflicting models of the lithospheric structure and plate movement.

In this study, the international research team – called Hi-CLIMB (Himalayan-Tibetan Continental Lithosphere during Mountain Building) – was able to create new in-depth images of the Earth’s structure beneath the Himalayas.

“The interface between the subducting Indian plate and the upper Himalayan and Tibetan crust is the Main Himalayan thrust fault, which reaches the surface in southern Nepal,” Nabelek said.

The new images show it extends from the surface to mid-crustal depths in central Tibet, but the shallow part of the fault sticks, leading to historically devastating mega-thrust earthquakes.

“The deep part is ductile and slips in a continuous fashion. Knowing the depth and geometry of this interface will advance research on a variety of fronts, including the interpretation of strain accumulation from GPS measurements prior to large earthquakes,” Nabelek said.

The researchers found that the lower part of the Indian crust slides about 450 kilometers under the southern Tibetan plate and the mantle appears to shear off and break into sub-parallel segments.

The researchers found evidence that subduction in the fault zone has been occurring from both the north and south sides – likely at different times in its geologic history. (ANI)

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Antarctica’s plumbing system more dynamic than previously believed

September 2, 2009 By Leave a Comment

Washington, Sept 2 (ANI): Scientists, using space-based lasers on a NASA satellite have created the most comprehensive inventory of lakes that actively drain or fill under Antarctica’s ice, which has revealed a continental plumbing system that is more dynamic than previously thought.

“Even though Antarctica’s ice sheet looks static, the more we watch it, the more we see there is activity going on there all the time,” said Benjamin Smith of the University of Washington in Seattle, who led the study.

Unlike most lakes, Antarctic lakes are under pressure from the ice above. That pressure can push melt water from place to place like water in a squeezed balloon.

The water moves under the ice in a broad, thin layer, but also through a linked cavity system. This flow can resupply other lakes near and far.

Understanding this plumbing is important, as it can lubricate glacier flow and send the ice speeding toward the ocean, where it can melt and contribute to sea level change.

But figuring out what’s happening beneath miles of ice is a challenge.

Researchers led by Smith analyzed 4.5 years of ice elevation data from NASA’s Ice, Cloud and land Elevation satellite (ICESat) to create the most complete inventory to date of changes in the Antarctic plumbing system.

The team has mapped the location of 124 active lakes, estimated how fast they drain or fill, and described the implications for lake and ice-sheet dynamics.

Smith, Helen Fricker, a geophysicist at the Scripps Institution of Oceanography, and colleagues extended their elevation analysis to cover most of the Antarctic continent and 4.5 years of data from ICESat’s Geoscience Laser Altimeter System (GLAS).

By observing how ice sheet elevation changed between the two or three times the satellite flew over a section every year, researchers could determine which lakes were active.

They also used the elevation changes and the properties of water and ice to estimate the volume change.

Only a few of the more than 200 previously identified lakes were confirmed active, implying that lakes in East Antarctica’s high-density “Lakes District” are mostly inactive and do not contribute much to ice sheet changes.

Most of the 124 newly observed active lakes turned up in coastal areas, at the head of large drainage systems, which have the largest potential to contribute to sea level change.

According to Robert Bindschadler, a glaciologist at NASA’s Goddard Space Flight Center, “The survey shows that most active subglacial lakes are located where the ice is moving fast, which implies a relationship.” (ANI)

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‘Spiderbots’ inside Mount St Helens may detect impending volcanic eruption

August 15, 2009 By Leave a Comment

Washington, August 15 (ANI): NASA scientists have placed about a dozen monitoring ‘spiderbots’ inside the volcanic crater in Mount St Helens in the US, which are high-tech devices that can detect an impending eruption.

Mount St. Helens is one of the most active volcanoes in the US. Its most devastating eruption in 1980, and the most recent seen here in 2004.

According to a report in National Geographic News, about a dozen so-called Spiders were placed on Mount St. Helens in July.

The pods, designed to go where no human can, were lowered by helicopter inside and around the volcano center.

“We can detect the differences between snow falling off of a branch, an animal running by, wind, a thunderstorm and the very subtle signatures of magma moving at depth, perhaps even kilometers beneath the surface of the earth,” said Steve Chien, Principal Scientist, Autonomous Systems, NASA Jet Propulsion Laboratory .

The pods form a virtual wireless network and communicate with each other and a NASA satellite called Earth Observing-1, or EO-1.

Each pod contains a seismometer, a GPS receiver, an infrared sounder to sense explosions, and a lightning detector.

According to Chien, “They have the ability to recognize different kinds of events such as seismic events, earthquakes, that are basically indications that something is happening at the volcano.”

“In the context of volcano monitoring, we want to have the best educated guess to make decisions that will save life and properties,” said Sharon Kedar, Geophysicist, NASA /Jet Propulsion Laboratoy.

NASA would like to someday use this same technology on the surface of Mars to study atmospheric events like dust storms, which are mini-tornadoes, as well as seismic activity. (ANI)

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Cell phone towers can help predict the next big flood

July 8, 2009 By Leave a Comment

Tel Aviv, July 7 (ANI): Researchers from Tel Aviv University, Israel, have said that they can predict the intensity of the next big flood by using common cell phone towers across the United States.

Their model, which analyzes cell phone signals, adds a critical component to weather forecasting never before available.

“By monitoring the specific and fluctuating atmospheric moisture around cell phone towers throughout America, we can cheaply, effectively and reliably provide a more accurate ‘critical moisture distribution’ level for fine-tuning model predictions of big floods,” said Professor Pinhas Alpert, a geophysicist and head of Tel Aviv University’s Porter School for Environmental Education.

Cell phone towers emit radio waves that are diminished by moisture in the air, a factor that can be used to improve model warnings on flood levels.

In addition, the researchers measured the rainfall distributions and were able to accurately estimate the size of impending floods before they struck.

This was demonstrated in post-analysis of two case-studies of floods in the Judean Desert in Israel, where cell phone towers and flash floods are abundant.

Using real data measurements collected from the towers, the researchers demonstrated how microwave links in a cellular network correlated with surface station humidity measurements.

The data provided by cell phone towers is the missing link weather forecasters need to improve the accuracy of flood forecasting.

“Our method provides reliable measurement of moisture fields near the flood zone for the first time,” said Professor Alpert. “This new tool can add to the bigger picture of understanding climate change patterns in general,” he added.

“Accurate predictions of flooding were difficult before because there haven’t been enough reliable measurements of moisture fields in remote locations,” Professor Alpert further added.

Using the signals collected from cell phone towers as they communicate with base stations and our handsets, weather forecasters will now have a crucial missing piece of information for flood prediction that they never had before.

It will permit forecasters and residents alike to more accurately gauge the danger they face from an impending flood. (ANI)

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Current sea ice least in 800 years

July 2, 2009 By Leave a Comment

Washington, July 2 (ANI): A new research, which has reconstructed the extent of ice in the sea between Greenland and Svalbard from the 13th century to the present indicates that there has never been so little sea ice in 800 years as there is now.

Scientists from the Niels Bohr Institute in Denmark conducted the research.

There are of course neither satellite images nor instrumental records of the climate all the way back to the 13th century, but nature has its own ‘archive’ of the climate in both ice cores and the annual growth rings of trees.

“We have combined information about the climate found in ice cores from an ice cap on Svalbard and from the annual growth rings of trees in Finland and this gave us a curve of the past climate,” explained Aslak Grinsted, geophysicist with the Centre for Ice and Climate at the Niels Bohr Institute at the University of Copenhagen.

In order to determine how much sea ice there has been, the researchers needed to turn to data from the logbooks of ships, which whalers and fisherman kept of their expeditions to the boundary of the sea ice.

The ship logbooks are very precise and go all the way back to the 16th century. They relate at which geographical position the ice was found.

Another source of information about the ice are records from harbours in Iceland, where the severity of the winters have been recorded since the end of the 18th century.

By combining the curve of the climate with the actual historical records of the distribution of the ice, researchers have been able to reconstruct the extent of the sea ice all the way back to the 13th century.

Even though the 13th century was a warm period, the calculations show that there has never been so little sea ice as in the 20th century.

“We see that the sea ice is shrinking to a level which has not been seen in more than 800 years,” concluded Aslak Grinsted. (ANI)

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Delaware Earthquake – Delaware Online – Earthquake in Delaware – Delaware News – Wdel – Earthquake Delaware – US geological officials – South Jersey residents – Minor Earthquake Rattles Dishes in South Jersey –

July 1, 2009 By Leave a Comment

Delaware Earthquake – Delaware Online – Earthquake in Delaware – Delaware News – Wdel – Earthquake Delaware – US geological officials – South Jersey residents – Minor Earthquake Rattles Dishes in South Jersey

US geological officials have confirmed that the South Jersey residents felt on Wednesday morning minor earthquake in the area,  no injuries or damage have been reported

A geophysicist for the National Earthquake Center in Golden, Colo., John Bellini, says the temblor hit about 9:45am and measured about 2.8 on the Richter scale  and was centered near Wilmington, Del., but the epicenter was changed several hours later to Salem County, NJ, two miles southeast of Pennsville, was not a magnitude to cause injuries or more than incidental damage.

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Earth’s magnetic poles may wander due to ocean currents

June 20, 2009 By Leave a Comment

London, June 20 (ANI): A controversial new hypothesis has proposed that oceans’ currents are responsible for the slow wandering of the Earth’s magnetic poles.

According to a report in New Scientist, the theory has been put forward by physicist Gregory Ryskin of Northwestern University in the US.

Most scientists agree that the magnetic field is generated by movements of the molten iron that makes up Earth’s outer core.

However, Ryskin said that his idea that ocean movements may affect the field is worth investigating.

“Oceans could drag the field along global currents, and they could also generate their own weak magnetic field,” he said.

Classical fluid dynamics says that a conductive fluid – even a weak one like seawater – will drag magnetic field lines along with it as it moves, though the field lines may “slip” and fall behind.

Ryskin has calculated how the Earth’s magnetic field lines are dragged by ocean currents and modified by the oceans’ own magnetic field lines.

He found that the motion fits snugly with observations of how the magnetic field has been changing with time, in particular, how the geomagnetic poles have been moving.

In addition, weak electric currents generated as seawater flows through the Earth’s magnetic field generate secondary “oceanic” magnetic fields.

Ryskin included the effect of these magnetic fields in his calculations.

He also showed that the places on the globe where distortions on the geomagnetic field lines are greatest correspond to areas where ocean currents are strongest.

“The oceans almost certainly slightly modify the geomagnetic field observed at the surface due to electric currents flowing within the Earth and in the ionosphere,” said geophysicist Raymond Hide of Imperial College London.

“Geophysicists would be in Ryskin’s debt if he could improve on what others have already done. I wish him well,” he added. (ANI)

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Scientists discover gigantic alp-like mountain range buried under Antarctic ice

February 25, 2009 By Leave a Comment

Washington, Feb 25 (ANI): An international team of scientists has confirmed the existence of an European Alps-like mountain range in Antarctica, which is buried under more than four kilometers (2.5 miles) of ice.

The team has also created a detailed picture of the rugged landscape that is suspected to have caused the massive East Antarctic Ice Sheet to form.

“Working cooperatively in some of the harshest conditions imaginable, all the while working in temperatures that averaged -30 degrees Celsius, our seven-nation team has produced detailed images of last unexplored mountain range on Earth,” said Michael Studinger, of Columbia University’s Lamont-Doherty Earth Observatory, the co-leader of the U.S. portion of the Antarctica’s Gamburstev Province (AGAP) project.

“As our two survey aircraft flew over the flat white ice sheet, the instrumentation revealed a remarkably rugged terrain with deeply etched valleys and very steep mountain peaks,” he added.

According to geophysicist Fausto Ferraccioli, of the British Antarctic Survey (BAS), who led the U.K. science team, the initial AGAP findings, while extremely exciting, also raise additional questions about the role of the Gamburtsevs in birthing the East Antarctic Ice Sheet, which extends over more than 10 million square kilometers atop the bedrock of Antarctica.

“We now know that not only are the mountains the size of the European Alps but they also have similar peaks and valleys,” he said. “But this adds even more mystery about how the vast East Antarctic Ice Sheet formed,” he added.

“If the ice sheet grew slowly, then we would expect to see the mountains eroded into a plateau shape. But, the presence of peaks and valleys could suggest that the ice sheet formed quickly. Our big challenge now is to dive into the data to get a better understanding of what happened millions of years ago,” he added.

The AGAP survey area covered roughly 2 million square kilometers of the ice sheet.

The AGAP data will help scientists to determine the origin of the East Antarctic Ice Sheet and the Gamburtsevs’ role in it.

It will also help them to understand the role the subglacial aquatic system plays in the dynamics of ice sheets, which will, in turn, help reduce scientific uncertainties in predictions of potential future sea level rise. (ANI)

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Scientists unveil first gravity map of moon’s far side

February 16, 2009 By Leave a Comment

London, Feb 16 (ANI): The first detailed map of the gravity fields on the Moon’s far side has shown that craters there are different than those on the near side, which could reveal more about the Moon as it was billions of years ago, when magma flowed across its surface.

According to a report in New Scientist, the new gravity map was collected by the Japanese lunar satellite Kaguya, which released two small probes into orbit around the Moon in 2007.

The motions of the three spacecraft, which are sensitive to variations in the Moon’s gravity field, were measured by tracking their radio signals.

Crucially, while the main Kaguya spacecraft was on the far side of the Moon and therefore out of direct contact with Earth, one of the small probes relayed its signals to Earth.

The resulting map, which is the first detailed one completed of the Moon’s far side, shows that craters on the far side have a markedly different gravity signature from those on the side that always faces Earth.

That suggests that billions of years ago, there might have been large differences in the temperature or thickness of the Moon’s two halves.

“It’s fabulous new data,” said Walter Kiefer, a planetary geophysicist with the Lunar and Planetary Institute in Houston, Texas, who was not part of the study. “We haven’t been able to get a good look at the far side until now,” he added.

Most of the large craters on the Moon formed more than 3.8 billion years ago. These were partly filled in by magma that flowed on the surface before the Moon cooled and its geological activity died down.

But, a number of craters also seem to have been filled in from below.

Researchers believe material from the mantle also rose up in craters, since these are sites where impacts had thinned the Moon’s crust.

The new Kaguya measurements reveal some craters on the far side that seem to have been filled only with mantle.

These craters have higher-than-normal gravity at the centre, surrounded by a thick ring of low gravity that closely matches the original low elevation of the crater.

It is not yet clear what these new crater measurements suggest about the early Moon.

In order for these structures to survive, the lunar far side must have been too cool and stiff to allow the mantle at the craters’ centres to smooth out much over time, according to team leader Noriyuki Namiki, of Japan’s Kyushu University.

“The surface had to be very rigid to support these structures,” Namiki said. (ANI)

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Alien atmosphere helped unfreeze ancient Earth

February 15, 2009 By Leave a Comment

Washington, Jan 14 (ANI): Analysis of the chemical composition of 635-million-year-old rocks from the Norwegian island chain of Svalbard has revealed oxygen trapped inside the rocks, which suggests ancient Earth once had an alien atmosphere that might have helped melt millions of years’ worth of deep freeze.

According to a report in National Geographic News, the analysis shows a surprisingly low amount of a particular type, or isotope, of oxygen.

Reduced levels of this isotope are linked to high levels of carbon dioxide in the atmosphere, and the new data suggest ancient Earth might have had 300 to 1,000 times more CO2 than current levels.

An atmosphere so rich in CO2 would still be breathable by modern standards, but it would place limits on the growth of life as we know it.

“The numbers indicate a very, very different world” than scientists had previously assumed, said study leader Huiming Bao of Louisiana State University.

Bao and colleagues think their finding supports the “snowball Earth” theory, which says that snow and ice accumulation worldwide once reached a threshold that caused the entire planet to stay frozen for millions of years.

Most scientists believe Earth could only emerge from such a state after ten million years or more, after atmospheric CO2 built up enough to finally trigger melting and lead to a rapid thaw.

Bao and colleagues analyzed a compound called sulfate from rocks dated to the Neoproterozoic era, which lasted from a billion to 542 million years ago.

Sulfate forms when a charged sulfur atom binds with four oxygen atoms. The complete molecule is highly stable, which makes sulfate a useful tool for studying what types of oxygen atoms were present when the sulfate formed.

In the Svalbard study, Bao and colleagues looked at the sulfate-containing mineral carbonate and found very low levels of an oxygen isotope called O-17.

Previously, Bao and a different set of co-authors had examined sulfate in another mineral called barite in samples from south China and West Africa dated to roughly the same time period.

Those rocks had also shown a low amount of O-17.

Given that the abnormal isotope ratios occurred in several locales, University of California, San Diego, chemist Mark Thiemens beleives the results are associated with a widespread phenomenon.

The atmospheric effects were, “if not global, at least equatorial,” said Thiemens.

According to geophysicist Raymond Pierrehumbert, of the University of Chicago, the result “underscores what I call ‘Neoproterozoic weirdness,’ namely that there are a lot of strange geochemical signatures that indicate that the climate is doing something radically different from what it was doing before or since.” (ANI)

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Venus may have had continents and oceans in its ancient past

February 15, 2009 By Leave a Comment

London, Jan 14 (ANI): In a new research, scientists have claimed to detect evidence for granite highlands on Venus in data almost two decades old, which suggests that the planet may have once been far more like Earth, with oceans and continents.

According to a report in Nature News, the data includes nighttime infrared emissions coming from the surface of Venus, which was detected by NASA’s Galileo spacecraft in 1990.

Analyzing these data, an international team led by planetary scientist George Hashimoto, now at Okayama University, Japan, found that Venus’s highland regions emitted less infrared radiation than its lowlands.

One interpretation of this lower infrared emission from the highlands, according to the authors, is that they are composed largely of ‘felsic’ rocks, particularly granite.

Granite, which on Earth is found in continental crust, requires water for its formation.

“This is the first direct evidence that early in the history of the Solar System, Venus was a habitable planet with plenty of water,” said Dirk Schulze-Makuch, an astrobiologist at Washington State University in Pullman.

“The question is how long Venus remained habitable. But this gives new impetus for the search for microbial life in Venus’s lower atmosphere,” he added.

Before Galileo, researchers had believed that only radar could see through the dense clouds of sulphuric acid in Venus’s atmosphere to the surface, according to co-author Kevin Baines, a scientist at NASA’s Jet Propulsion Laboratory in Pasadena, California.

“Detecting the surface in the infrared is a breakthrough,” he said.

The possible presence of granite also suggests that tectonic plate movement and continent formation may have occurred on Venus, as well as recycling of water and carbon between the planet’s mantle and atmosphere.

According to geophysicist Norm Sleep of Stanford University in California, the implication of continent formation is “quite significant”.

Venus might have once been almost entirely underwater, although without further geochemical data, we don’t know whether this early ocean’s temperature was 30 degree Celsius or 150 degree Celsius, he added.

“Whether tepid or boiling, any ocean on Venus would have lasted only a few hundred million years. As the Sun became hotter and brighter, the planet experienced a runaway greenhouse effect,” Sleep explained.

Nowadays, the planet is a paragon of the uninhabitable, with an atmosphere of 96 percent carbon dioxide and a surface temperature of around 460 degrees C.

“Any life on Venus that hadn’t figured out how to colonize the cloud tops a billion years after the planet’s formation would have been in big trouble,” said Sleep. (ANI)

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Collapse of West Antarctic Ice Sheet may pose threat to nations in southern Indian Ocean

February 7, 2009 By Leave a Comment

Washington, Feb 6 (ANI): University of Toronto geophysicists have predicted that following the collapse of West Antarctic Ice Sheet, the coastlines of North America and of nations in the southern Indian Ocean will face the greatest threats from the resulting rising sea levels.

“There is widespread concern that the West Antarctic Ice Sheet may be prone to collapse, resulting in a rise in global sea levels,” said geophysicist Jerry X. Mitrovica, who, along with physics graduate student Natalya Gomez and Oregon State University geoscientist Peter Clark, are the authors of the new study.

“We’ve been able to calculate that not only will the rise in sea levels at most coastal sites be significantly higher than previously expected, but that the sea-level change will be highly variable around the globe,” said Gomez.

“Scientists are particularly worried about the ice sheet because it is largely marine-based, which means that the bedrock underneath most of the ice sits under sea level,” said Mitrovica.

“The West Antarctic is fringed by ice shelves which act to stabilize the ice sheet. These shelves are sensitive to global warming, and if they break up, the ice sheet will have a lot less impediment to collapse,” he added.

According to Mitrovica, if the West Antarctic Ice Sheet collapses, the rise in sea levels around many coastal regions will be as much as 25 per cent more than expected, for a total of between six and seven metres if the whole ice sheet melts.

“That’s a lot of additional water, particularly around such highly populated areas as Washington, D.C., New York City, and the California coastline,” he added.

“There is still some important debate as to how much ice would actually disappear if the West Antarctic Ice sheet collapses – some fraction of the ice sheet may remain quite stable,” said Mitrovica.

“But, whatever happens, our work shows that the sea-level rise that would occur at many populated coastal sites would be much larger than one would estimate by simply distributing the meltwater evenly,” he added. (ANI)

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Ancient asteroid may have created biggest known landslide on Mars

January 7, 2009 By Leave a Comment

Washington, Jan 7 (ANI): Scientists have said that an asteroid may have triggered a landslide on Mars billions of years ago, which is the size of the entire United States, and the largest known anywhere.

The finding could help solve the origin mystery of Mars’s Arabia Terra region, a vast, midlevel plateau between the planet’s smooth northern lowlands and rugged southern highlands.

According to a report in National Geographic News, estimated at about 1,000 miles (1,600 kilometers) wide, the giant asteroid is believed to have struck Mars’s northern hemisphere billions of years ago.

The cataclysm is thought to have given the planet its topographical split personality — smooth in the north, but bumpy down south.

The impact site became the smooth, low-lying Borealis Basin, about 6,000 miles (10,000 kilometers) across. The southern part of the planet became highlands—in places several miles higher than the basin.

The border of the two regions is sharply defined, except for the Arabia Terra zone. This odd middle ground is neither highlands nor basin.

Until recently, the reason for the region had been unknown.

Arabia Terra is a relic of the giant asteroid impact, according to geophysicist Jeff Andrews-Hanna, of the Colorado School of Mines.

This unusual midland was created when a U.S.-size portion of the highlands broke free and slid 180 miles (300 kilometers) northward, down into the southern rim of the Borealis Basin, Andrews-Hanna said.

In other words, three of Mars’s largest geographic features — the Borealis Basin, the highlands, and Arabia Terra — were formed “virtually instantaneously, in a single catastrophic collision,” the geophysicist said

According to Andrews-Hanna, the first clue that Arabia Terra was formed via landslide is that the relatively flat region has steep slopes at both its northern and southern edges, which is like a giant step.

Similar features occur in other large impact craters, many of which have bull’s-eye patterns—concentric circles or ellipses of steep ridges separated by gently sloping plateaus.

The similarity of Arabia Terra to these other craters indicates that it too might have been created by an impact.

Another clue is that, at Arabia Terra, the inner rim of the Borealis Basin doesn’t line up with its inner rim elsewhere on the planet.

Instead, the rim juts northward by about 300 kilometers, as if a landslide had smudged the clean break seen in areas to the west and east. (ANI)

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