(Credit:
Peking University and Tsinghua University)
That tiny, plastic-looking black cube up there can absorb up to 180 times its own weight in toxic waste without absorbing any water. How? As with just about every amazing and/or inexplicable scientific breakthrough nowadays, the answer is spelled N-A-N-O.
Researchers at Peking and Tsinghua universities, both in Beijing, have adapted carbon nanotubes into a sponge-like material that can be squeezed dry, which sounds like extremely exciting news for the infomercial cleaning product industry. One minor detail:
Since carbon nanotubes are hydrophobic, there's no modification required to make them not absorb water.
For the record, that includes mysteriously blue infomercial demo water, so there goes that. If not absorbing 20 times as much water as its leading competitor, what exactly is this new type of sponge good for? Environmental cleanup, evidently. See, instead of just dropping dispersants into the middle of an oil or chemical spill--which forces the spill to simply absorb into the water--these light and porous nanosponges could float in water and be used to sop up the spill, after which they could theoretically be wrung dry and reused, like so:
The scientists detail their findings in Advanced Materials. It's an amazing idea, but I get the feeling that carbon nanotube sponges, riskily abbreviated as CNT sponges, won't exactly be cheap.
This story originally appeared on Gizmodo.
As chip geometries get infinitesimally small, IBM is looking to DNA to make the manufacture of future chips feasible.
On Monday, IBM researchers and collaborator Paul W.K. Rothemund, of the California Institute of Technology, announced an advancement of a method to arrange DNA origami structures on surfaces compatible with today's semiconductor manufacturing equipment.
Low concentrations of triangular DNA origami bind to wide lines on a lithographically patterned surface.
(Credit: PRNewsFoto/IBM)"The cost involved in shrinking (chip) features to improve performance is a limiting factor in keeping pace with Moore's Law and a concern across the semiconductor industry," said Spike Narayan, a manager in the Science & Technology division of IBM Research, in a statement.
Moore's Law, named after Intel co-founder Gordon Moore, states that the number of transistors that can be placed on an integrated circuit doubles roughly every two years. For more than four decades, chip manufacturers have been able to consistently shrink chip geometries, allowing Moore's Law to remain on track.
But this may not be sustainable for chips with geometries under 22 nanometers. By 2014, the high cost of semiconductor manufacturing equipment will threaten Moore's Law, "altering the fundamental economics of the industry," according to a report released in June by iSuppli. New chip plants typically cost billions of dollars to build, and the tab goes up as chip circuits get smaller.
Individual triangular DNA origami adhere to a template with properly sized triangular features.
(Credit: PRNewsFoto/IBM)IBM uses DNA molecules as scaffolding--where millions of carbon nanotubes could be deposited and self-assembled into precise patterns by sticking to the DNA molecules. This approach might provide a way to reach sub-22-nanometer lithography--down to 6 nanometers--more economically, according to a paper to be published in the September issue of Nature Nanotechnology, entitled "Placement and orientation of DNA nanostructures on lithographically patterned surfaces." It was co-authored by IBM and Caltech scientists.
"The utility of this approach lies in the fact that the positioned DNA nanostructures can serve as scaffolds, or miniature circuit boards, for the precise assembly of components, such as carbon nanotubes, nanowires, and nanoparticles," according to IBM. The combination of self-assembly with today's fabrication technology eventually could lead to substantial savings in the most expensive and challenging part of the chipmaking process, IBM said.
The lithographic templates, for chip fabrication, were made by IBM using traditional semiconductor techniques, the same used to make the chips found in today's computers, to etch out patterns.
While computers continue to get smaller, they're constantly being pushed to do more. Whether they're doubling as a phone, a camera, or an MP3 player, there seems to be no end to the tasks we expect them to carry out. And as always, we say we want them to "do all that stuff and be smaller."
(Credit:
IBM)
A limitation of the miniaturization process is that the more computers are asked to do, the more memory they require. One of the computer's basic elements, the transistor, could soon reach its miniaturization limit. The smaller we make transistors, the more susceptible they are to quantum phenomena like electrons tunneling through the barriers between wires. Which, while ticklish for the barrier, can just be really annoying.
This has apparently annoyed researchers at the U.K.'s University of Nottingham, as well, albeit for different reasons. This transistor dilemma has led them to look into the viability of carbon nanotubes to help create fast, cheap, and compact memory that uses little power.
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