Seaweed could be the key to long-lasting electric car batteries

Lithium-sulfur batteries are theoretically ideal for powering gadgets. They have more than twice the energy density of lithium-ion packs, but at a much lower cost thanks to sulfur's dirt-cheap price. There's just one problem: sulfur dissolves, giving...

Researchers develop energy saving smart window that filters out heat and / or light

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In the heat of summer, either you shut the windows and crank up the AC, or pull down the blinds and stumble around in the gloom. At least, that was the case. A team at the Lawrence Berkeley National Laboratory has developed a new smart window that lets people choose what they want to let into their home, filtering out visible light, near-infra-red light, or both. Using a thin layer of nanocrystals that change state when electricity is passed through, will enable people to save on home energy bills by keeping the bulk of the Sun's heat out of the home without sacrificing the natural light. Now all we have to do is hook this up with one of Samsung's touchscreen windows and we'll never have to leave home again.

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Via: PhysOrg

Source: Lawrence Berkeley National Laboratory

Scientists capture images of molecules forming atomic bonds

Berkeley Lab spies a molecule forming atomic bonds

For most of us, molecular bonding only really exists as a classroom concept. Some scientists at Lawrence Berkeley National Laboratory can now claim more tangible knowledge, however: they're the first to have taken truly clear snapshots of bonding in progress. While trying to create graphene nanostructures and observe them with an atomic force microscope, a lab team spotted molecules forming their individual, atom-level links during a chemical reaction. The resulting shots were nearly textbook material, too -- as the molecules were neatly placed on a flat surface, the researchers identified the order and nature of each bond. While the images will only be immediately useful for the nanostructure research at hand, they may add a welcome dash of reality to future chemistry lessons.

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Via: Phys.org

Source: Lawrence Berkeley National Laboratory

Alt-week 9.29.12: 3D pictures of the moon, 4D clocks and laser-controlled worms

Alt-week peels back the covers on some of the more curious sci-tech stories from the last seven days.

Altweek 92912 3D pictures of the moon, 4D clocks and lasercontrolled worms

Dimensions, they're like buses. You wait for ages, and then three come along at once. And then another one right after that. While that might be about where the analogy ends, this week sees us off to the moon, where we then leap from the third, right into the fourth. Once there, we'll learn how we could eventually be controlled by lasers, before getting up close and personal with a 300 million-year old bug. Sound like some sort of psychedelic dream? Better than that, this is alt-week.

Continue reading Alt-week 9.29.12: 3D pictures of the moon, 4D clocks and laser-controlled worms

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Alt-week 9.29.12: 3D pictures of the moon, 4D clocks and laser-controlled worms originally appeared on Engadget on Sat, 29 Sep 2012 18:00:00 EDT. Please see our terms for use of feeds.

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Researchers make unsuitable parts work as solar cells, could lead to cheaper panels

Researchers make unsuitable parts work as solar cells, could lead to cheaper panels

Harnessing the power of the sun is a tricky business, but even the past few weeks have seen some interesting developments in the field. In this latest installment, researchers from the Lawrence Berkeley National Laboratory and the University of California have figured out a way of making solar cells from any semiconductor, potentially reducing the cost of their production. You see, efficient solar cells require semiconductors to be chemically modified for the current they produce to flow in one direction. The process uses expensive materials and only works with a few types of semiconductors, but the team's looking at using ones which aren't normally suitable -- the magic is to apply an electrical field to them. This field requires energy, but what's consumed is said to be a tiny fraction of what the cell's capable of producing when active, and it means chemical modification isn't needed.

The concept of using a field to standardize the flow of juice isn't a new one, but the team's work on the geometrical structure of the cells has made it a reality, with a couple of working prototypes to satisfy the skeptics. More of these are on the way, as their focus has shifted to which semiconductors can offer the best efficiency at the lowest cost. And when the researchers have answered that question, there's nothing left to do but get cracking on commercial production. For the full scientific explanation, hit up the links below.

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Researchers make unsuitable parts work as solar cells, could lead to cheaper panels originally appeared on Engadget on Sat, 11 Aug 2012 11:34:00 EDT. Please see our terms for use of feeds.

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