“Society is vulnerable, so we need to prepare ourselves as individuals,” said Dan Eliasson of the Swedish civil contingencies agency, which is in charge of the project. “There’s also an information deficit in terms of concrete advice, which we aim to provide.”
Defence pamphlet shows how population can prepare in event of attack and contribute to country’s ‘total defence’
Jon Henley European affairs correspondent.
In 1965, a renowned Princeton University physicist theorized that ferroelectric metals could conduct electricity despite not existing in nature.
For decades, scientists thought it would be impossible to prove the theory by Philip W. Anderson, who shared the 1977 Nobel Prize in physics. It was like trying to blend fire and water, but a Rutgers-led international team of scientists has verified the theory and their findings are published online in Nature Communications.
“It’s exciting,” said Jak Chakhalian, a team leader of the study and Professor Claud Lovelace Endowed Chair in Experimental Physics at Rutgers University-New Brunswick. “We created a new class of two-dimensional artificial materials with ferroelectric-like properties at room temperature that don’t exist in nature yet can conduct electricity. It’s an important link between a theory and an experiment.”
Are we ready?
Batteries powered by radioactive materials have been around for more than a century, but what they promise in power they usually lose in bulk.
Not so with a new kind of power source, which combines a novel structure with a nickel isotope to pack ten times more power than an electrochemical cell of the same size. The only question is, are we ready to go nuclear?
A team of Russian researchers have put a new spin on technology that uses the beta decay of a radioactive element to create differences in voltage.
A first-of-its-kind copper and graphite combination discovered in basic energy research at the U.S. Department of Energy’s Ames Laboratory could have implications for improving the energy efficiency of lithium-ion batteries, which include these components.
“We’re pretty excited by this, because we didn’t expect it,” said Pat Thiel, an Ames Laboratory scientist and Distinguished Professor of Chemistry and Materials Science and Engineering at Iowa State University. “Copper doesn’t seem to interact strongly or favorably with graphitic materials at all, so this was a big surprise. It really challenges us to understand the reasons and mechanisms involved.”
The scientists bombarded graphite in an ultra-high vacuum environment with ions to create surface defects. Copper was then deposited on the ion-bombarded graphite while holding it at elevated temperature, at 600–800 K. The synthetic route created multilayer copper islands that are completely covered by graphene layer(s).
Left: Conventional composite battery design, with 2D stacked anode and cathode (black and red materials). Right: New 3D nanohybrid lithium-ion battery design, with multiple anodes and cathodes nanometers apart for high-speed charging. (credit: Cornell University)
Cornell University engineers have designed a revolutionary 3D lithium-ion battery that could be charged in just seconds.
In a conventional battery, the battery’s anode and cathode (the two sides of a battery connection) are stacked in separate columns (the black and red columns in the left illustration above). For the new design, the engineers instead used thousands of nanoscale (ultra-tiny) anodes and cathodes (shown in the illustration on the right above).
Long before our Sun formed it was nothing more than a bunch of material floating listlessly in a large cloud of gas, dust, and debris. These space clouds, called nebulas, are where stars and planets are born, eventually coalescing into larger bodies which become slaves to gravity and form systems such as the one we currently reside in. But what factors affect star and planet formation, and what ultimately determines the type of stars that form? Using observations of one very special nebula, scientists now think have begun to understand.
One of the biggest hurdles in studying these molecular space clouds is that telescopes can only produce a 2D picture of them, making it impossible to model the interior structure and movements of the dust and gasses. Researchers focused on the cloud known as Musca, which lies hundreds of light years away from Earth, but is still close enough to study. The scientists discovered that this particular cloud is “singing.”
