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The researchers have found a way to use silicon nanowires to give rechargeable lithium ion batteries--used in laptops, iPods, video cameras, and mobile phones--as much as 10 times more charge. This potentially could give a conventional battery-powered laptop 40 hours of battery life, rather than 4 hours.
The new batteries were developed by assistant professor Yi Cui and colleagues at Stanford University's Department of Materials Science and Engineering.
"It's not a small improvement," Cui said. "It's a revolutionary development."
Citing a research paper they wrote, published in Nature Nanotechnology, Cui said the increased battery capacity was made possible though a new type of anode that utilizes silicon nanowires. Traditional lithium ion batteries use graphite as the anode. This limits the amount of lithium--which holds the charge--that can be held in the anode, and it therefore limits battery life.
Silicon anodes have the "the highest theoretical charge capacity" according to Cui's paper, but they expand when charging and shrink during use: a cycle that causes the silicon to be pulverized, degrading the performance of the battery. For 30 years, this dead end stumped researchers, who poured their battery life-extending energy into improving graphite-based anodes.
Cui and his colleagues looked at this old problem and overcame it by constructing a new type of silicon nanowire anode. In Cui's anode, the lithium is stored in a forest of tiny silicon nanowires, each with a diameter that is a thousandth of the thickness of a sheet of paper. The nanowires inflate to four times their normal size as they soak up lithium, but unlike previous silicon anodes, they do not fracture.
Cui said there are a few barriers to commercializing the technology.
"We are working on scaling up and evaluating the cost of our technology," Cui said. "There are no roadblocks for either of these."
Cui has filed a patent on the technology and is considering formation of a company or an agreement with a battery manufacturer. He expects the battery to be commercialized and available within "several years," pending testing.
Alex Serpo of ZDNet Australia reported from Sydney.
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Electronics & Computers Deals here!
OTOH, can this be adapted to electric cars. With a current range of somewhere around 50-120 miles on a single charge they are pretty much dead. But if that can be extended to 500 to 1200 miles now that would be a very practical car, able to take long weekend vacations on a single charge, or at least have a range that would allow one to drive all day and recharge overnight to continue the next day.
EEStor
EEStor Inks Deal with Lockheed Martin
Cedar Park, Texas-based EEStor signed an exclusive international deal with defense contractor Lockheed Martin, EEStor said Wednesday. Under the new deal, Lockheed Martin will integrate EEStor's ceramic batteries into military applications. EEStor claims its batteries potentially have 10 times the energy density of lead-acid batteries at half the price (see Earth2Tech post and VentureBeat post). EEStor plans to begin mass production by the end of this year.
Still worth celebrating, though.
The trick is preventing cascading chain reaction for the battery by proper design.
- Batteries for Cars
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by Alex Serpo
January 16, 2008 7:19 PM PST
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1 | 2 | Next 10 Comments >>Firstly thanks for reading my story, it's been hugely popular around the network.
Since there has been so many comments, I will try and address some of your questions.
Even with a tenfold increase in battery life, these new Li-Ion batteries would not compared to the energy density (in kilojoules per gram) when compared to octane (read, petrol).
By my calculation a standard Li-Ion batteries comes out at around 500 joules per gram, as such this battery could be up to 5000 joules per gram.
Compare that to octane, 47,000 joules per gram, this still gives it about 10 as much energy per unit weight as these improved batteries.
Octane can be generated as a biofuel, which (at least in theory) makes it carbon neutral.
In regard to electric cars, it is my opinion the best technology for electric cars is still hydrogen based fuel cells (although methanol fuel cells are pretty good).
However it could still be great for laptops, ipods etc, were fuel cells aren't practical.
-- Alex Serpo, ZDNet Australia.