cool

Continuum continues their series Open for Branding, where they are sharing, from start to finish, their latest branding project for the new, nomadic Design Museum Boston.

Wow. Last week, we posted our Design Museum Boston branding concepts for feedback, and more than 1700 people checked out our survey and 274 completed it. The greatest part: everyone aligned--Continuum, Design Museum Boston, and you—on which directions were the strongest.

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Unlike infectious diseases and news, behavior change spreads faster through online networks that have many close connections instead of many distant ties. Redundancy is key, as people are more likely to engage in a behavior if they see many others doing it.
“There has been a lot of theory about the difference between information and behavior spreading,” said economic sociologist Damon Centola of the Massachusetts Institute of Technology, author of the study published September 3 in Science. “We’ve assumed that they are the same, but you can imagine that behavior is not really like that, that you need to be convinced.”
The research has important implications for people designing online communities intended to change or maintain a behavior, like weight watchers or online health communities, Centola said.
To do the experiment, he created an internet-based health community and invited people already participating in other online health forums to join. Over 1,500 people signed up to participate, and they were placed anonymously in one of two different kinds of networks: a random network with many distant ties (above left), or a clustered network with many overlapping connections (above right).
Users in both networks had the same number of assigned ‘health buddies.’ They couldn’t contact their buddies directly, but they could see how their buddies rated content on the site, and could receive emails informing them of their buddies activities. Centola said he deliberately didn’t pay the volunteers, so they would participate out of legitimate interest in the site’s content.
In six different trials over a period a few weeks, Centola seeded the site with information about an online health forum and tracked people as they signed up and participated.
In the clustered network, 54 percent of the people signed up for the forum, compared to 38 percent in the random network, and almost four times as fast. Not surprisingly, Centola also found the more friends people had that also signed up, the more likely they were to return to the forum to participate.
“I feel that the greatest contribution of this study has to do with the very unusual social experiment that it relies on,” said economist Tomas Barrios of Stanford University, who wasn’t involved in the study. “Usually experimental data for social experiments comes form hard to swallow lab settings, or if not, very low tension, low risk social situations that can be ethically intervened by experimenters.”
Barrios also said many researchers have made mathematical models to understand the spread of behavior, but that the models have have little application in predicting what will actually happen in the real world.
These studies cannot be done yet using data from Facebook or Twitter Centola says, because the network is constantly changing and too gigantic to download all at once.
Image: Damon Centola
See Also:

Gene Makes Some Drink More When Other Boozers Are Around
Slime Mold Grows Network Just Like Tokyo Rail System
Circuit-Tweaking Reverse Engineers a Gene Network
Network Theory Could Regulate Human Reproduction
Magnetic Nanoparticles Can Remotely Control Worms
Kindness Breeds More Kindness, Study Shows

Guest post by Phil Patton.

Surprisingly self-effacing among the high profile wit and higher profile designers of Alessi, the new Ovale line of tableware from Ronan and Erwan Bouroullec may sum up the current design zeitgeist.
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By Alasdair Wilkins, io9
The atmosphere of a young exoplanet didn’t fit any of our existing models for what gas giants should look like. But when astronomers added huge dust clouds, it was a perfect fit, perhaps revealing a larger truth about gas giants.
The planet in question is HR 8799 b, a gas giant about seven times the mass of Jupiter. It’s one of three gas giants revolving around the star HR 8799, located about 1,300 light-years away. The system was first discovered in 2008, and now astronomers have been able to perform spectroscopic analysis of the planets. These analyses are extraordinarily powerful, giving us close approximations of the planet’s chemical composition, cloud properties, and even temperature.
We can figure out the temperature of an exoplanet by measuring the amount of methane in its atmosphere. According to the almost non-existence methane levels on HR 8799, its temperature couldn’t be any cooler than about 1700 degrees Fahrenheit. But other metrics, such as the planet’s apparent youthful age and the amount of energy it’s sending out, suggest it should be about 250 degrees cooler than that, assuming our current models are right.
As it turns out, our models are wrong, or at least they didn’t take into account the possibility of massive dust clouds on HR 8799 b. When those clouds are added into the equation, the data fits together perfectly and explains the 250 degree swing. Because this particular gas giant is one of the youngest we’ve ever observed and analyzed, it’s quite possible that this extreme dustiness is just a natural part of a gas giant’s infancy, which tells us something about the beginnings of our own solar system’s four gas giants.

Images: 1) NASA, ESA, G. Bacon (STSci). 2) NASA.
See Also:

Top 5 Most Extreme Exoplanets
Exoplanet Hunter’s First Data Withholds the Good Stuff
New Technique Finds Gaseous Metals in Exoplanet Atmospheres
First Direct Measurement of an Exoplanet’s Light Spectrum

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A new batch of sharp Martian close-ups from NASA's HiRISE camera were released on September 1. HiRISE (High Resolution Imaging Science Experiment) has been circling Mars on the Mars Reconnaissance Orbiter for four years now, taking dramatic photos of the red planet with a telephoto lens to make any paparazzi jealous. The camera can focus on objects the size of a beach ball from more than 180 miles away.

The 236 new images, taken between July 8 and July 31, cover the planet practically from pole to pole. They zoom in on terrain ranging from volcanic cones to cratered planes, from wind-swept dunes to crusts of ice. The images even capture evidence of ongoing geological processes on Mars today, like fresh craters that may have formed between January and June of this year.

These are some of our favorites from the new set. But since January, the HiRISE team has been letting the public point the camera. You can go suggest new terrain to explore using their "HiWish" feature.

Above: These volcanic cones were formed by hot lava running over water or ice. The heat from the lava boiled the water underneath, and the water burst upwards in an exploding bubble of lava. The explosion threw chunks of molten and solid lava into the air to gather into the cones. These cones are similar in size and shape to cones found in Iceland.

Image: NASA/JPL/University of Arizona



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A reinterpretation of the fossil record suggests a new answer to one of evolution’s existential questions: whether global mass extinctions are just short-term diversions in life’s preordained course, or send life careening down wholly new paths.
Some scientists have suggested the former. Rates of species diversification — the speed at which groups adapt and fill open ecological niches — seemed to predict what’s flourished in the aftermath of past planetary cataclysms. But according to the calculations of Macquarie University paleobiologist John Alroy, that’s just not the case.
“Mass extinction fundamentally changes the dynamics. It changes the composition of the biosphere forever. You can’t simply predict the winners and losers from what groups have done before,” he said.
Alroy was once a student of paleontologist Jack Sepkoski, who in the 1980s formalized the notion that Earth has experienced five mass extinctions in the 550 million years since life became durable enough to leave a fossil record. Graphs of taxonomic abundance depict lines rising steadily as life diversifies, plunging precipitously during each extinction, and rising again as life proliferates anew.
As the fossil record is patchy and long-term evolutionary principles still debated, paleobiologists have historically disagreed about what these extinctions mean. Some held that, in the absence of extinctions, species would diversify endlessly. The Tree of Life could sprout new branches forever. Others argued that each taxonomic group had limits; once it reached a certain size, each branch would stop growing.
Sepkoski’s calculations put him on the limits side of this argument. He also proposed that, by looking at the rate at which each group produced new species, one could predict the winners and losers of each mass extinction’s aftermath. Groups that diversified rapidly would flourish. Their destiny was already established.
“It’s a clockmaker vision of evolution. Each group has fixed dynamics, and if there’s an extinction, it just messes it up a bit,” said Alroy. “That’s what I’m challenging in this paper. There are limits, and that’s why we don’t have a trillion species. But those limits can change.”

Alroy crunched marine fossil data in the Paleobiology Database, which gathers specimen records from nearly 100,000 fossil collections around the world. He used a statistical adjustment method designed to reduce the skewing influences of paleontological circumstance — the greater chances of finding young fossils rather than old, the ease of studying some types of rock rather than others.
Historical species diversity among marine animals of Cambrian, Paleozoic and Modern origin.
The analysis, published September 2 in Science, produced what Alroy considers to be the most accurate reflection of extinction dynamics to date. And while his data supported the notion that each group’s diversity eventually hits a limit, he didn’t find Sepkoski’s correlation between pre-mass-extinction diversity rates and post-extinction success. Each mass extinction event seemed to change the rules. Past didn’t indicate future.
In an accompanying commentary, paleontologist Charles Marshall of the University of California, Berkeley noted that Alroy’s statistical methods still need review by the paleobiology community. The Paleobiological Database, for all its thoroughness, might also be incomplete in as-yet-unappreciated ways. “There will be no immediate consensus on the details of the pattern of diversity,” he wrote. But “the pieces are falling into place.”
Enough pieces have come together for Alroy to speculate on his findings’ implication for the future, given that Earth is now experiencing another mass extinction. Starting with extinctions of large land animals more than 50,000 years ago that continued as modern humans proliferated around the globe, and picking up pace in the Agricultural and Industrial ages, current extinction rates are far beyond levels capable of unraveling entire food webs in coming centuries. Ecologists estimate that between 50 and 90 percent of all species are doomed without profound changes in human resource use.
In the past, many evolutionary biologists thought life would eventually recover its present composition, said Alroy. In 100 million years or so, the same general creatures would again roam the Earth. “But that isn’t in the data,” he said.
Instead Alroy’s analysis suggests that the future is inherently unpredictable, that what comes next can’t be extrapolated from what is measured now, no more than a mid-Cretaceous observer could have guessed that a few tiny rodents would someday occupy every ecological niche then ruled by reptiles.
“The current mass extinction is not going to simply put things out of whack for a while, and then things will go back to where we started, or would have gone anyway,” said Alroy. Mass extinction “changes the rules of evolution.”
Images: 1) A fossil skull of Dunkleosteus, an apex predator fish that lived between 380 million and 360 million years ago, and had what is believed to be history’s most powerful bite./Michael LaBarbera, courtesy of The Field Museum. 2) Graph of species diversity among marine animals of Cambrian, Paleozoic and Modern origin./Science.
See Also:

Ecosystem Engineering Could Turn Sprawl Into Sanctuary
9 Environmental Boundaries We Don’t Want to Cross
Death Star Off the Hook for Mass Extinctions
A New Explanation for Ancient Mass Extinction
Latest Extinction is the Greatest
Megafauna Extinctions Not Entirely Humans’ Fault

Citations: “The Shifting Balance of Diversity Among Major Marine Animal Groups.” By J. Alroy. Science, Vol. 329 No. 5996, September 3, 2010.
“Marine Biodiversity Dynamics over Deep Time.” By Charles R. Marshall. Science, Vol. 329 No. 5996, September 3, 2010.
Brandon Keim’s Twitter stream and reportorial outtakes; Wired Science on Twitter. Brandon is currently working on a book about ecological tipping points.

Just north of a truck stop along Interstate 80 in Battle Mountain, Nevada, lies evidence that the Earth’s magnetic field once went haywire.
Magnetic minerals in 15-million-year-old rocks appear to preserve a moment when the magnetic north pole was rapidly on its way to becoming the south pole, and vice versa. Such “geomagnetic field reversals” occur every couple hundred thousand years, normally taking about 4,000 years to make the change. The Nevada rocks suggest that this particular switch happened at a remarkably fast clip.
Anyone carrying a compass would have seen its measurements skew by about a degree a week — a flash in geologic time. A paper describing the discovery is slated to appear in Geophysical Research Letters.
It is only the second report of such a speedy change in geomagnetic direction. The first, described in 1995 based on rocks at Steens Mountain, Oregon, has never gained widespread acceptance in the paleomagnetism community. A second example could bolster the theory that reversals really can happen quickly, over the course of years or centuries instead of millennia.
“We’re trying to make the case that [the new work] is another record of a superfast magnetic change,” says lead author Scott Bogue, a geologist at Occidental College in Los Angeles.

Researchers aren’t sure why the geomagnetic field reverses itself. Many think it must have something to do with what creates the field in the first place — convective motions of liquid iron in the planet’s spinning outer core.
Bogue and his colleague, Jonathan Glen of the U.S. Geological Survey in Menlo Park, California, went to Nevada to study a series of well-preserved lava flows. As each flow cooled, it preserved the orientation of the magnetic field at the time, frozen like a tiny compass needle in the rock’s magnetic crystals.
One particular flow caught the scientists’ attention because it seemed to carry a complex magnetic history. This lava, Bogue says, initially started to cool and then was heated again within a year as a fresh lava flow buried it. The fresh lava remagnetized the crystals within the rock below, causing them to reorient themselves a whopping 53 degrees. At the rate the lava would have cooled, says Bogue, that would mean the magnetic field was changing direction at approximately 1 degree per week.
The Steens Mountain rocks have been reported to preserve a change of 6 degrees per day. That rate was so high — imagine trying to navigate when a compass changes by multiple degrees per day — that many scientists challenged the report. One line of argument held that the liquid outer core simply can’t generate magnetic field changes that rapidly. Another held that, even if the changes were happening, they wouldn’t be observable at the surface because the Earth’s internal electrical conductivity would screen the signals out.
The Nevada rocks bolster the idea that such changes could be happening, says Bogue — even if scientists still can’t explain why.
Not all experts are convinced by the new paper. Dennis Kent, a paleomagnetist at Rutgers University in Piscataway, New Jersey, says it would be “a curious coincidence” to have two brief lava flows just happen to cool and capture a 53-degree change in direction, when reversals happen only a few times per million years.
The last stable reversal occurred 780,000 years ago. Some geologists argue the Earth is overdue for a reversal and might even be entering one now, as the geomagnetic field has been getting weaker over the past 150 years or more.
But apocalyptic SyFy channel movies to the contrary, nobody should worry about waking up one morning to geomagnetic havoc, says Bogue. “To geologists a polarity reversal is a nearly instantaneous thing that changes a global feature of the Earth — it’s really a spectacular phenomenon,” he says. “But if you were alive when it was happening, it probably wouldn’t be that big a deal.”
Image: Scott Bogue
See Also:

Earth’s Magnetic Field Is 3.5 Billion Years Old
Cockroaches Use Earth’s Magnetic Field to Steer
Reverse-Engineering the Quantum Compass of Birds
The Geomagnetic Apocalypse — And How to Stop It
Jupiter’s Magnetic Moon Generates Spectacular Light Show
Solar Slumber May Have Been Caused by Magnetic Flows

String theory has finally made a prediction that can be tested with experiments — but in a completely unexpected realm of physics.
The theory has long been touted as the best hope for a unified “theory of everything,” bringing together the physics of the vanishingly small and the mindbendingly large. But it has also been criticized and even ridiculed for failing to make any predictions that could be checked experimentally. It’s not just that we don’t have big enough particle accelerators or powerful enough computers; string theory’s most vocal critics charge that no experiment could even be imagined that would prove it right or wrong, making the whole theory effectively useless.
Now, physicists at Imperial College London and Stanford University have found a way to make string theory useful, not for a theory of everything, but for quantum entanglement.
“We can use string theory to solve problems in a different area of physics,” said theoretical physicist Michael Duff of Imperial College London. “In that context it’s actually useful: We can make statements which you could in principle check by experiment.” Duff and his colleagues describe their findings in a paper in Physical Review Letters September 2.
String theory suggests that matter can be broken down beyond electrons and quarks into tiny loops of vibrating strings. Those strings move and vibrate at different frequencies, giving particles distinctive properties like mass and charge. This strange idea could unite all the fundamental forces, explain the origins of fundamental particles and connect Einstein’s general relativity to quantum mechanics. But to do so, the theory requires six extra dimensions of space and time curled up inside the four that we’re used to.

To understand how these extra dimensions could hide from view, imagine a tightrope walker on a wire between two high buildings. To the tightrope walker, the wire is a one-dimensional line. But to a colony of ants crawling around the wire, the rope has a second dimension: its thickness. In the same way that the tightrope walker sees one dimension where the ants see two, we could see just three dimensions of space while strings see nine or ten.
Unfortunately, there’s no way to know if this picture is real. But although string theorists can’t test the big idea, they can use this vision of the world to describe natural phenomena like black holes.
Four years ago, while listening to a talk at a conference in Tasmania, Duff realized the mathematical description string theorists use for black holes was identical to the mathematical description of certain quantum systems, called quantum bits  or qubits.
Qubits form the backbone of quantum information theory, which could lead to things like ultrafast computers and absolutely secure communication. Two or more qubits can sometimes be intimately connected in a quantum state called entanglement. When two qubits are entangled, changing one’s state influences the state of the other, even when they’re physically far apart.
“As I listened to his talk, I realized the kind of math he was using to describe qubit entanglement was very similar to mathematics I had been using some years before to describe black holes in string theory,” Duff said. When he looked into it, the mathematical formulation of three entangled qubits turned out to be exactly the same as the description of a certain class of black holes.
In the new study, Duff and his colleagues push the similarity one step further. They used the mathematics of stringy black holes to compute a new way to describe four entangled qubits, an open question in quantum information theory.
“We made statements that weren’t previously known using string theory techniques,” Duff said. “Whether the result is some fundamental principle or some quirk of mathematics, we don’t know, but it is useful for making statements about quantum entanglement.”
What’s more, these statements are precise and experimentally provable, unlike previous suggestions for ways to test string theory, Duff says.
“So in a way, there’s bad news and good news in our paper,” he said. “The bad news is, we’re not describing the theory of everything. The good news is, we’re making a very exact statement which is either right or wrong. There’s no in between.”
Duff emphasized that this is only a test of string theory as it relates to quantum entanglement, not as a description of the fundamental physics of the universe. The battle over string theory as a theory of everything rages on.
“Already I can imagine enemies sharpening their knives,” Duff said.
And they are. A chorus of supporters and critics, including Nobel laureate and string theory skeptic Sheldon Glashow and string theorists John Schwarz of Caltech, James Gates of the University of Maryland, and Juan Maldacena and Edward Witten of the Institute for Advanced Study in Princeton agree that Duff’s argument is “not a way to test string theory” and has nothing to do with a theory of everything.
Mathematician Peter Woit of Columbia University, author of the blog Not Even Wrong, thinks even claiming that the new paper is a test of quantum entanglement is going too far.
“Honestly, I think this is completely outrageous,” he said. Even if the math is the same, he says, testing the quantum entangled system would only tell you how well you understand the math.
“The fact that the same mathematical structure appears in a quantum mechanical problem and some model of black holes isn’t even slightly surprising,” he said. “It doesn’t mean that one is a test of the other.”
Witten takes a more optimistic view of the theory’s chances, pointing out that the mathematics of string theory have turned out to be coincidentally useful in other areas of physics before.
“In general, this kind of work shows that string theory is useful, and in fact by now it has been useful in many different ways,” Witten said in an email to Wired.com.
“One might surmise that a physics theory that has proved to be useful in so many different areas of physics and math is probably on the right track,” he added. “But that is another question.”
Via Universe Today
Image: Entangled string. Flickr/Whatknot
See Also:

Physics Prof Proposes String Theory Test (But It’ll Cost Us …
A Test for String Theory After All? Or Just PR?
How To Test for an 11-Dimension Universe? Stay Tuned…
Large Hadron Collider: Best- and Worst-Case Scenarios
Quantum Computing Thrives on Chaos
Quantum Computer Simulates Hydrogen Molecule Just Right

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Chemical analysis of the bones of ancient Sudanese Nubians who lived nearly 2000 years ago shows they were ingesting the antibiotic tetracycline on a regular basis, likely from a special brew of beer. The find is the strongest yet that antibiotics were previously discovered by humans before Alexander Fleming discovered penicillin in 1928.
“I’m going to ask Alexander Fleming to hand back his Nobel Prize,” joked chemist Mark Nelson, who works on developing new tetracyclines at Paratek Pharmaceuticals and is lead author of the paper published June in the American Journal of Physical Anthropology.
Nelson found large amounts of tetracycline in the bones tested from the ancient population, which lived in the Nubian kingdom (present day Sudan) between 250 A.D. and 550 A.D. and left no written record.
“The bones of these ancient people were saturated with tetracycline, showing that they had been taking it for a long time,” Nelson said in a press release August 30. “I’m convinced that they had the science of fermentation under control and were purposely producing the drug.”
“This discovery will provide a whole new framework for understanding the relationship between microbes and antibiotics,” said anthropologist Dennis Van Gerven of University of Colorado at Boulder. “There might have been other populations that were also doing the same thing, anywhere that there were these microbes. This is going to drive other scientists to start this search, and that is incredibly important.”
Scientists have suspected this population was ingesting tetracycline since they first noticed a florescent yellow-green appearance of the bones under ultraviolet light, indicative of tetracycline.
“When we reported that in 1981, it was met with a lot of skepticism,” said anthropologist George Armelagos of Emory University, who made the original discovery and is co-author of this new study. “If you were unwrapping an Egyptian mummy and suddenly it had Ray-Ban sunglasses on it, that’s what it was like with us.”
Tetracycline latches on to calcium and gets deposited in bones, which is how it can be detected it in fossils. The ultraviolet light technique said little about how much tetracycline there was in the bone, and it was hard to convince others it wasn’t simply a produced of microbial contamination of the bones, or a one-time beer event.
Nelson was able to solve the problem by dissolving the bones in hydrogen flouride, the nastiest acid on the planet, he said. He was able to clearly identify the amount and identity of the tetracycline in the bones. It was in all the bones, including those of a four-year-old child.
Armelagos, who specializes in reconstructing ancient diets, proposed that the Nubians made the tetracycline in their beer. There is evidence they knew how to make it, he says. Tetracycline is produced by a soil bacteria called streptomyces, which is how it was discovered by modern society in the 1940s. Streptomyces thrives in warm, arid regions such as that of ancient Nubia, and likely contaminated a batch of beer.
They must have known how to propagate the beer because they were doing it to make wine, Nelson says. There was also so much of it in their bones that it is near impossible that the tetracycline-laced beer was a fluke event.
To make sure that making the antibiotic beer was possible, Armelagos had his graduate students give it a try.
“What they were making wasn’t like a Bud Light but a cereal gruel,” Armelagos said. “My students said that it was ‘not bad,’ but it is like a sour porridge substance. The ancient people would have drained the liquid off and also eaten the gruel.”
The Nubians likely noticed the antibiotics cured them of bacterial infection. It may have had negative effects as well: If taken in too large quantities the antibiotic can also cause iron deficiency because it latches on to the iron in the body.
Streptomyces produces a golden-colored bacterial colony that would have floated on top of the beer and likely encouraged its propagation. Gold was revered by the ancient cultures.
When and why the antibiotic beer secret was lost is a mystery. It is not the first technology to disappear with the disappearance of cultures. Armelagos is continuing to look for the tetracycline in the bones of different cultures. He says he has already found preliminary evidence it is in bones of people who date to as late as 1300 to 1400 A.D.
Armelagos hopes this find might also help explain why animals have been found with antibiotic resistance in Northern Africa where there is no previous evidence of antibiotics being used.
About a quarter of the grain in Africa is still made into beer, Armelagos says.
Images: 1) Ancient Egyptian figures show workers grinding, baking and fermenting grain to make beer and bread./Andreas Praefcke. 2) Green florescence in Nubian skeletons indicating tetracycline-labeled bone./Armelagos.
See Also:

Science + Geek + Beer = Awesomely Geeky Science Beer
Barley + Space = Space Beer!
Why Geologists Love Beer
Fossils Suggest Menu That Made Humans Possible
Ötzi the Iceman May Have Had Funeral Ceremony
Stone Age Europeans Get Older and Colder
New Find Pushes Age of Stone Tools Back A Million Years

By Duncan Geere, Wired UK
The uncharacteristically snowy weather that hit Northern Europe and North America in the winter of 2009/10 was caused by a rare combination of two separate weather oscillations in the Atlantic and Pacific, claim meteorologists.
The harsh winter and heavy snow surprised forecasters, arriving with temperatures at the lowest they’d been for nearly 30 years. Some climate skeptics cited the conditions as evidence against climate change, while other people pointed out that most climate change predictions include an increase in extreme weather events.
But the research, published in Geophysical Research Letters, claims that neither are correct, and that the freak weather was actually caused by an unusual match-up of a moderately strong El Niño event, and an extremely strongly negative North Atlantic oscillation.

Each has a different effect on the weather. An El Niño event tends to push storm systems towards the equator, making the weather in the US and Northern Europe wetter than normal. The North Atlantic Oscillation, on the other hand, doesn’t cause precipitation, it just makes it very cold. When they combine, you get very cold, wet, conditions — snow.
Richard Seager, a meteorologist at the Lamont Doherty Earth Observatory at Columbia University is one of the co-authors of the paper. He told the BBC: “The NAO was probably as negative as it’s ever been in the instrumental record, which goes back to the early 1800s. This was a once in a century type of event.” Investing in a snow plough for the coming winter is probably unwise, therefore.
As for those who raised the spectre of climate change, Seager is scathing in his dismissal: “Weather will continue to be weather. You have to average over a lot of weather to get the climate trends. There doesn’t seem to be any need to evoke anything else other than that.”
Image: Snow covered Great Britain on January 7, 2010./NASA.
See Also:

East Coast Blizzard Seen From Space
Russian Heat, Asian Floods May Be Linked
Pakistan’s Climate Change Floods, Seen From Above
MIT: Your Meteorologist Needs an Army of Drones
Pakistan’s Climate Change Floods, Seen From Above
Reader Photo Gallery: Crazy Dust Storm Turns Sydney Red



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