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  • Hi, it's me, your friendly neighborhood microbe enthusiast here,

  • just popping by to say that we're now using viruses to make batteries.

  • Like the kind you could use in your car.

  • So, that's just very casual and fine and not a big deal and I'm not freaking out at all.

  • Okay, let's back it up.

  • At its core, this innovation is about exploiting the thing that viruses do best: DNA hijacking.

  • See, viruses are a continual head-scratcher for us because they're not technically alive;

  • they contain genetic materialeither DNA or RNA, depending on what kind of virus we're talking about

  • but they can't replicate on their own.

  • They have to inject their genetic material into a living cell

  • and get that cell to replicate their genetic material for them.

  • They're kinda like microscopic pirates.

  • And while that makes them dangerous when it comes to disease,

  • it can also be really helpful when it comes to bioengineering.

  • There's one particularly pioneering team at MIT that's using viruses for their own devices.

  • They recognized that while viruses may insert their genome into our cells for destructive purposes,

  • we can also insert information into their genome to make stuff.

  • They're working with the M13 bacteriophage,

  • and a bacteriophage is a kind of virus that only infects bacteria,

  • and whose circular genome is relatively simple and easy to manipulate.

  • Scientists expose batches of this virus to the material they want it to latch onto, like a specific kind of metal.

  • Then, natural or engineered mutations in that virus's genome

  • will alter the virus' surface to be able to latch onto the material of choice.

  • Then scientists take the viruses that have properly 'learned' to latch onto the material

  • and pop them into the bacteria that virus would normally infect,

  • which then make millions of copies of those modified viruses.

  • If you repeat this process over and over, those bacteria basically become viral replication factories

  • that can pump out a finely-honed viral tool that does your bioengineering bidding.

  • So, that's super cool.

  • But how the heck do you make something like a metal-hugging virus into something like… a battery?

  • Well, the kind of metal matters.

  • Scientists can make a batch of viruses that latch onto cobalt oxide.

  • Or another batch that adheres to manganese oxide.

  • That's the beautiful thing about genetic modification in relatively simple organismsit's kinda just cut and paste.

  • You could do this for tons of elements on the periodic table,

  • but if the particular materials that I just mentioned sound familiar,

  • it's because we use them in some batteries.

  • The extra cool thing about this technique is not only that these viruses can be engineered to get metal

  • to glom onto them, but alsothose metal-coated viruses can then start to stick to each other.

  • And this forms what are called nanowiresthat's metal-coated virus nanowires

  • which can be used in battery electrodes.

  • Back in 2009, the MIT team was able to make a lithium ion battery using this viral assembly technique

  • and the battery worked! It powered an LED light!

  • Now the team is also working on using these microbial factories to make lithium-oxygen batteries,

  • also called lithium-air batteries.

  • That's literally a kind of battery where oxygen is what spurs the chemical reaction

  • that makes the battery work.

  • That means that with a continual supply of oxygen

  • as opposed to a finite supply of an electrolyte within the battery cell

  • a lithium oxygen battery could theoretically store ten times more energy

  • in relation to its mass than a lithium ion alternative.

  • Viruses are uniquely suited to building nanowires out of nanomaterials

  • because they already exist and function and replicate on the micro and nanoscale,

  • so we're just hacking into nature's existing tiny toolbox instead of having to build it all from scratch.

  • But maybe the most exciting thing about this viral battery production process is just how clean it could be.

  • Manufacturing electrodes the old-fashioned way can result in toxic byproducts

  • and requires very high temperatures,

  • whereas all that's needed here is genetically engineered viruses, water, and the metal

  • which, granted, does still come with its own set of issues around mining, etc.

  • And lithium oxygen batteries themselves have their own set of limitations.

  • They're currently highly reactive.

  • You have to remove impurities from the oxygen before you feed it to the battery,

  • and they still have relatively low charging efficiency.

  • To continue pursuing this exciting battery production technique for all kinds of batteries,

  • the MIT team is now focusing on getting their viruses in order

  • literally, having them grow in more ordered 3D structures as opposed to random ones.

  • So, all of this technology is still very much in the research and development phase,

  • but with techniques like viral-mediated electrode assembly,

  • maybe we're closer to seeing a virus-powered car on the road

  • than any of us would have thought before this video.

  • If you want more on crazy awesome virus research, check out this video here

  • and subscribe to Seeker for all your viral newsmicrobial and otherwise.

  • Let us know down in the comments what other virus-related topics you want to see us cover

  • and as always, thanks for watching.

  • I'll see you next time.

Hi, it's me, your friendly neighborhood microbe enthusiast here,

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