Posted on 06/30/2015 12:08:20 PM PDT by Red Badger
A team of researches affiliated with Samsung's Advanced Institute of Technology, along with colleagues from other institutions in Korea has found a way to greatly extend lithium-ion battery life. In their paper published in the journal Nature Communications, the team describes their new technique and the results they achieved using it.
Consumers want their phone batteries to last longerthat is no secret, and battery life has been extended, but mostly due to improved efficiency of the electronics that depend on it. Researchers at phone companies and elsewhere have been working hard to find a way to get more power out of the same size battery but have to date, not made much progress. In this new effort, the researchers looked to silicon and graphene for a better battery.
The team started by using silicon as the material for their anode, rather than the traditional graphiteit is denser and therefore can hold more chargeand is something other researchers have tried before. The problem has always been that in order to charge it, lithium must be added, which causes the anode to expand, a deal breaker for small electronic devices. To circumvent that problem, the researches grew carbide-free graphene (to keep it from forming they developed a chemical vapor deposition process which included using a mild oxidant) on its surface creating a protective and restrictive coating. In addition to preventing expansion, the graphene also helped prevent the silicon from breaking down over time (which occurs due to constant expanding and contracting).
Testing showed that the arrangement resulted in a battery that had an initial energy density that was 1.8 times that of conventional batteries, and held steady at 1.5 times after repeated use. Translated to the real world that would mean a battery that at least initially, would last nearly twice as long as conventional batteries. That is impressive, of course, but the fly in the ointment is the graphenedespite a lot of time, effort and money invested, scientists still have not figured out a way to manufacture the stuff in bulk, which means, that the new battery design will not be available to consumers until a way can be found to produce the graphene.
Explore further: Novel battery uses light to produce power
More information: Silicon carbide-free graphene growth on silicon for lithium-ion battery with high volumetric energy density, Nature Communications 6, Article number: 7393 DOI: 10.1038/ncomms8393
Abstract Silicon is receiving discernable attention as an active material for next generation lithium-ion battery anodes because of its unparalleled gravimetric capacity. However, the large volume change of silicon over chargedischarge cycles weakens its competitiveness in the volumetric energy density and cycle life. Here we report direct graphene growth over silicon nanoparticles without silicon carbide formation. The graphene layers anchored onto the silicon surface accommodate the volume expansion of silicon via a sliding process between adjacent graphene layers. When paired with a commercial lithium cobalt oxide cathode, the silicon carbide-free graphene coating allows the full cell to reach volumetric energy densities of 972 and 700 Wh l−1 at first and 200th cycle, respectively, 1.8 and 1.5 times higher than those of current commercial lithium-ion batteries. This observation suggests that two-dimensional layered structure of graphene and its silicon carbide-free integration with silicon can serve as a prototype in advancing silicon anodes to commercially viable technology.
SiC-free graphene growth on Si NPs. (a) A low-magnification TEM image of GrSi NP. (b) A higher-magnification TEM image for the same GrSi NP from the white box in a. (Insets) The line profiles from the two red boxes indicate that the interlayer spacing between graphene layers is ~3.4 Å, in good agreement with that of typical graphene layers based on van der Waals interaction. (c) A high-magnification TEM image visualizing the origins (red arrows) from which individual graphene layers grow. (d) A schematic illustration showing the sliding process of the graphene coating layers that can buffer the volume expansion of Si. Credit: Nature Communications 6, Article number: 7393 doi:10.1038/ncomms8393
Tech Ping!..................
Discussed was that batteries longevity will double, amongst other things. This is in line with the doubling point...
Interesting
Apparently their is a version of LI-ion's that use phosphate as part of the chemical mixture and they don't do the thermal run-a-way thing. I think race car and homebuilt airplane guys have found them and are trying them as the weight reduction vs. even a small lead-acid battery. The weight savings is a great deal. Something like a 3 lb battery will start a 150hp engine...
Maybe Moore’s Law applies to batteries, as well.................
For comparison, the energy density of gasoline is around 32 MJ/L, which is not quite nine times as much.
Of course, to turn gasoline into electricity requires heavy, bulky, noisy rotating equipment that weighs a lot, is dirty, vibrates, and ejects red-hot poison gas. A battery requires none of that.
Energy density info source.
Re: battery doubling - Moores law
Hoping we’re just about there.
Huge battery breakthroughs currently in play.
New battery company M24 is attracting big investment and may make Tesla regret their decision to go with a multi Billion dollar battery plant.
Thanks for the link, I will read later. Are you aware of the Israeli / Alcoa Aluminum Battery and Amy Prieto CSU Battery?
One of my gnomes attended a rubber-chicken auto diner / conference with a big kahuna in auto media world who was on the dais.
Discussed was that batteries longevity will double, amongst other things. This is in line with the doubling point...
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Would this be a doubling of the Tesla battery life (250 miles) or volt battery life (100 miles)
You’re welcome.
Yes, I’ve been following those battery developments, too.
Once cost-effective, durable, safe, lightweight batteries arrive, it will make personal defense laser diode array weaponry all the more practical!
I wonder, have they considered lead as an electrode?...........
Graphene ping.
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