Citrobacter freundii: can have concentrations of uranium in their bodies 300 times higher than in the surrounding environment.
Courtesy CDC
Looking toward the day uranium mines become depleted, Dr Masao Tanada is working on a sponge like material that can extract uranium from the ocean currents passing by Japan.
The world's oceans contain an estimated 4.5 billion tons of uranium, around 1,000 times the amount that is known to exist in uranium mines.
Japan is drawing up innovative plans to extract uranium from seawater in an attempt to end the country's reliance on imports for nuclear power stations. Telegraph.co.uk
This link to Next Big Future illustrates two proposals for mining the ocean for $720 trillion worth of Uranium.
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photo by Art Oglesby
This glass "skeleton" from a marine sponge can be seen at Collector's Corner.
Please contact us if you have questions about the rights on this image.
Marine sponge glass: photo by Art Oglesby; Glass structure formed by marine sponge.
One approach to creating devices on a molecular scale is to have such devices self-assemble similar to the way living things "grow".
David E. Morse is attempting to mimic how living organisms self-assemble complex shapes with nanoscale precision. The intricate glass structure pictured was assembled molecule by molecule by a species of marine sponge. The genes responsible for the glass structures encode for enzymes that serve as both a physical template for the structure and a catalyst for assembling molecular precursors into the desired material.
Morse and his colleagues begin with a solution of molecular precursors. The researchers then expose the solution to ammonia vapor, which, as it slowly diffuses into the solution, acts as a catalyst. The physical template for the material is the surface of the solution. At this surface, where the vapor concentration is greatest, the material forms a thin film.
"At first the crystals form at the [surface], but with time they begin to project down into the solution like stalactites growing down from the roof of a cave," Morse says. "What you end up with is a nanostructured thin film of semiconductor with very high surface area because of all the projecting thin plates or needles that project down into the solution. We are accessing structures that in some cases had never been achieved before. And in some cases we're discovering electronic properties that had never been known before for that class of materials," says Daniel Morse, professor of molecular genetics and biochemistry at UCSB, who led the project. The method works with a wide variety of materials. So far, he says, the group has made "30 different kinds of oxides, hydroxides, and phosphates."
Source article; Technology Review
A list of selected publications by Morse.
photo by Art Oglesby; Glass structure formed by marine sponge.
Please contact us if you have questions about the rights on this image.
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