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Power Technology

Stanford Develops Fast-Charging, Stable Aluminum Battery 142

An anonymous reader writes: Stanford researchers have announced the creation of an aluminum-ion battery that they say will charge quicker, last longer, and be generally safer than common lithium-ion batteries. "Aluminum has long been an attractive material for batteries, mainly because of its low cost, low flammability and high-charge storage capacity. For decades, researchers have tried unsuccessfully to develop a commercially viable aluminum-ion battery. A key challenge has been finding materials capable of producing sufficient voltage after repeated cycles of charging and discharging. ... For the experimental battery, the Stanford team placed the aluminum anode and graphite cathode, along with an ionic liquid electrolyte, inside a flexible, polymer-coated pouch." The researchers' main challenges now are getting the battery to produce a higher voltage and store energy at a higher densities.
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Stanford Develops Fast-Charging, Stable Aluminum Battery

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  • by MasseKid ( 1294554 ) on Monday April 06, 2015 @09:26PM (#49419629)
    "The researchers' main challenges now are getting the battery to produce a higher voltage and store energy at a higher densities."

    So basically, they're only challenges left are making it into a decent battery?
    • by msauve ( 701917 )
      I've developed a perpetual motion machine. My main challenge is getting it to work without energy input.
    • by Ken_g6 ( 775014 ) on Monday April 06, 2015 @09:40PM (#49419683)

      Just because it's not a good battery for your laptop - yet - doesn't mean it's not a good battery for other applications.

      Compare it to lead-acid, for instance. It's lighter, it's probably non-toxic (the electrolyte is unknown), and I'd be surprised if it were much more expensive. And it charges fast, so it probably discharges fast too. Sounds like a great starter battery for cars or scooters, etc.

      • Yeah, but if your energy density is so low that a supercapacitor beats it, you have nothing useful, as they will always have superior power density.

        • by dave420 ( 699308 )
          You might have a base to improve on, leading to better density than a supercapacitor. Just because it's not instantly jaw-dropping doesn't mean it's useless.
      • Another use for an inexpensive long lasting battery is to store energy from solar panels for dark periods. In this application storage density isn't the primary concern.

      • by Khyber ( 864651 )

        "The electrolyte is unknown"

        From like the third or fourth paragraph in the article:

        "The electrolyte is basically a salt that's liquid at room temperature"

        Molten salts, in an electrolyte, pretty much. Probably something like ethyl-methyl-imidazolium bis-(trifluoromethanesulfonyl)-imide

        • This is basically a large heater for MRE packages but controlled to make it useful in some way other than shorting out and creating heat. This isn't really new except for making it practical I guess.

      • No, if you go and chase down the original article the electrolyte is NOT unknown, but an anhydrous aluminium chloride/organic chemical. The cells the researchers are producing are putting out around 1.9 to 2 volts, and the cells are resilient over at least 7500 charge/discharge cycles. The cathode is graphite foam built on a nickel foam substrate, the anode is aluminium foil.

        To be honest, the only real kicker about the entire battery is the fact that water in the electrolyte severely reduces the performance

    • "A key challenge has been finding materials capable of producing sufficient voltage after repeated cycles of charging and discharging."

      they seem to have accomplished this.

      it is good news.

    • So basically, their only challenges left are making it into a decent battery?

      If you RTFA, they mention that it puts out close to 2 volts.
      While that's almost perfect as a replacement for lead-acid batteries, it's not enough to replace two AA batteries (2.4v/3v) or one lithium-ion (3.6~3.7v)

      • by Khyber ( 864651 )

        Almost 2V you say? Considering a single AA is 1.2, 1.5, or 1.6V (Ni-Zn) I could see this having plenty of use in AA format, depending upon capacity.

      • by gl4ss ( 559668 )

        i presume they mean actually it being effective at delivering the voltage. the single cell voltage doesn't matter so much, you can stack them anyways.

        I think they're just using voltage in the stub just as "electricity yo!" and meant that the density and practicality aren't there in it. perhaps the way they built their pouch is also non scalable easily..

      • If you RTFA, they mention that it puts out close to 2 volts.
        While that's almost perfect as a replacement for lead-acid batteries, it's not enough to replace two AA batteries (2.4v/3v) or one lithium-ion (3.6~3.7v)

        If it's sufficiently close to 2V then it will be an ideal replacement for Li-Ion, simply by doubling the number of cells. A fully-charged Li-Ion is 4.1 or 4.2 volts, not 3.7... Have you ever even charged an 18650A cell?

      • by necro81 ( 917438 ) on Tuesday April 07, 2015 @08:06AM (#49421695) Journal

        While that's almost perfect as a replacement for lead-acid batteries, it's not enough to replace two AA batteries (2.4v/3v) or one lithium-ion (3.6~3.7v)

        I would argue that the cell voltage is largely irrelevant. If you need to put more cells in series, it doesn't matter much. What matters more is the energy density - if you end up with twice as many cells (to get voltage equivalent to li-ion), but have equal or better energy density (Whr/kg or Whr/L) at equal or better cost, then you still have a win.

        • Exactly, I can get the equivalent voltage of a li-ion cell by stringing together lemons. Doesn't mean it would fit in the back of my cell phone.

    • So basically, they're only challenges

      No, they are not only challenges. Presumably, they are normal people.

      Why do supposedly educated people persist in making spelling errors that wouldn't be acceptable in second grade?

    • by gweihir ( 88907 )

      Like most other "wonder" battery technologies of recent years. I predict that this one will not materialize in any useful form either.

    • by unrtst ( 777550 )

      "The researchers' main challenges now are getting the battery to produce a higher voltage and store energy at a higher densities."

      So basically, they're only challenges left are making it into a decent battery?

      Add the other quote from the summary, "A key challenge has been finding materials capable of producing sufficient voltage after repeated cycles of charging and discharging".

      So, for decades now, the key challenge has been the thing that is currently the main challenge for the researchers? IE. no real change.

  • by dixonpete ( 1267776 ) on Monday April 06, 2015 @10:12PM (#49419841)
    "Battery "breakthroughs" need to state power *and* energy density (not the same thing), plus how long they last. They usually fail on energy."
    • by pushing-robot ( 1037830 ) on Monday April 06, 2015 @10:32PM (#49419951)

      True, but an Al-ion battery definitely has potential* [ornl.gov], even if this team hasn't achieved it yet.

      Al also has ~5x the physical density of Li at ~1/5th the price, so even if it doesn't outperform Li's energy density for a while it will still be better for many applications.

      * groan

    • by ras ( 84108 )

      Battery "breakthroughs" need to state power *and* energy density

      What if I told you I had a brand new battery to sell you. True, it only stores 0.14 WHr/kg (compared to 100WHr/kg for LiIon) and of course bugger all power density, but on the up side, the electrolyte is real cheap, and it's good for 10's of thousands of cycles.

      You probably tell me to piss off, but in doing to you have dismissed the most popular form of electricity storage we have - pumped storage. According to Wikipedia [wikipedia.org]. US stores and releas

      • I'd lay odds that's more the entire combined output of all rechargeable batteries in the country.

        I'll take that bet. If you add all the batteries in Tesla model S, Chevy Volt Nissan Leaf, Toyota, Prias, Mitsu i-MiEV, Ford Focus Electric, etc they account for more than 5MWh. Just 2/3rd of the Tesla production [hybridcars.com] accounts for over half the 5MWh.

      • TFA article mentions this new battery's potential for just that: buffering of surplus renewable energy. They'll need to achieve a reasonable energy density for these batteries to be practical and make economic sense (especially for residential applications), but energy density doesn't need to be on the cutting edge like EV batteries are.
  • No? I am unimpressed.

  • An aluminum ion battery would be a huge advance, especially (particularly) if it's cheaper.

    Doesn't look like they'll be ready in time for my battery replacement, but who knows.

    Ferret
  • Aluminium ... electrolyte ... stores large amounts of energy ... isn't this just an electrolytic capacitor?

Fast, cheap, good: pick two.

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