Why NASA is Building a Solid State Battery

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this is NASA they build Rockets telescopes and batteries yeah that's right of all the amazing NASA breakthroughs that have trickled down into our everyday lives things like CAT scans memory foam and the insulin pump none may be as gamechanging as NASA's recent solid state battery breakthrough NASA's Sabers battery might actually have just pulled off the holy Grill of Battery tech a high powerered solid state battery that could Electrify 90% of commercial Aviation so how does NASA's new battery change the game and just how big a deal is it are solidate batteries really the future of e-mobility let's figure this out together I'm Ricky and this is Two bit Da [Music] Vinci this video is sponsored by ATMO it may surprise you that NASA the National Aeronautics and Space Agency would put money into battery research but when you think about it it makes sense NASA makes things that fly and the only way you can do that is by making them as light and Powerful as possible so they can carry as much energy on board as possible and fly longer distances this is so typical in engineering there's always a trade-off so NASA does research on engines and energy sources trying to make them as energy dense and power dense as possible and for most of NASA's history that meant researching rocket engines ice turbines and rocket fuel but with everything going electric now that means batteries as well okay so here's what we know about NASA's battery so far about 4 years ago on October 1st 2019 NASA launched the estate architecture batteries for enhanced rechargeability and safety AKA project Sabers I don't know who comes up with these names but uh it's always a doozy the plan was to develop solid state batteries for commercial Aviation and Urban Air Mobility basically electric planes air taxis and flying cars the primary goal was to develop a battery that's safer more efficient more energy dense and more resilient than conventional lithium ion batteries the saber's battery uses a solid state electrolyte instead of the typical liquid or gel electrolytes we see in lithium on batteries today which is why it's called a solid state battery let's do a quick rundown on how batteries in general work so you can understand what we're talking about here most batteries like your typical lithium ion cell in your phone or laptop are made of three parts a cathode an anode and an electrolyte sandwich between the two the anode active material is where all the energy is stored when you use a battery to power a laptop for example the anode oxidizes and releases the electrons that move to the laptop circuits powering it you can think of the cathode as a bucket that receives all those electrons once they make it out of the laptop because they have to go somewhere right now this is the only thing that happened we'd have a buildup of positive charge in the anode and negative charge in the cathode because all the negative electrons filling up in the bucket and the reaction would quickly stop and that's where the separator and electrolyte come in the separator keeps the anode and cathode from short circuiting and it doesn't let electrons through only the ions the electrolyte in normal batteries is simp simply a salt dissolved in organic solvent which is flammable and that's what causes the fires we've seen on so many of these YouTube videos in the past in a solid electrolyte battery the electrolyte is well solid so you don't need to have liquid or gel that allows the ions to pass through it can actually pass through from the electrolyte itself this means much higher safety and potentially much better performance but there's other challenges one of the great pleasures of making these videos is all the research we get to do on really cool topics for instance we've done two videos on fires in Maui and Canada and it's got me thinking about air quality in a whole new way and I got to tell you about our sponsor this week atmo and this the atmo tube Pro this amazing little device is a 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out today links in the description huge thanks to atmo and you for supporting the show the head of Sabers Dr Roco vigano and his team had a Monumental task ahead of them they needed to find the right electrolyte material and an anode cathode combination that would perform better than lithium ion batteries it's a tall task then they had to design electrolyte that would be easy and cheap to make at scale one that wouldn't depend on rare materials and reach the supply chain bottlenecks down the road and one that would be safe to use both at ground level and at cruising altitudes it was anything but easy but they finally settled on the selenium sulfur chemistry we'll discuss why in a moment the team worked tirelessly for years tweaking the composition combining with other materials and in October 2022 they finally published the results we compared the Sab battery to the best performing lithium on batteries and this is what we found the news saers battery has a specific energy density of 500 WS per kogam which is almost twice that of the typical lithium ion battery making it around 40% lighter for the same amount of energy 40% is a huge Improvement it means you can get the same amount of energy in roughly half the weight so when we talk about energy density there's two ways of doing it gravimetrical energy density meaning weight and then volumetric meaning the amount of volume it takes up here's a really quick sidebar okay hydrogen is a amazing for energy density in terms of weight right hydrogen is a gas when you compress it it has a ton of energy by weight but it's really bad volum metrically and that's because the vessels that you need take up a ton of space so volumetric density for hydrogen bad gravimetric good so for Batteries is kind of the same thing so how does the volumetric energy density for the Sabers battery compare really good reaching over 800 W hours per liter lithium ion cells only reach about 500 W hours per liter this means saber batteries are also roughly 40% smaller than lithium on batteries in terms of volume picture your phone's battery being half the size and half the weight but performing just as well or picture exactly the same battery pack in your EV but giving you twice the range pretty cool right but the benefits don't stop there you can drive a nail right through it and it'll keep on working since there's no liquid that would drain out there's also no flammable organic solvent to catch fire so say goodbye to batteries that swell up and have ther thermal runaway reactions now this is crucial for airplanes lithium on batter's optimal temperature range is between 59f and 95° F such a narrow range requires active thermal management adding weight and complexity and reducing efficiency saber's operating temperature can go from 32° F around 0° C to 302° F 150° C which means it works safely and well in pretty much all flying conditions without a bulky an energy intensive thermal management system okay so let's put on our engineering hats for just a moment and dissect NASA's battery to see what makes it special compared to other solate batteries and I promise it'll be really brief the anode is simply made of metallic lithium now this is in contrast to most lithium on batteries that have graphite or silicon as the anode material a pure lithium anode is about as good as it gets so that's a really good start the cathode is a bit more complex it's made of a combination of sulfur selenium selenium sulfide compounds and a patented porous graphine called holy graphine they chose the lithium sulfur chemistry because it has a very high theoretical specific energy of 2,680 w hours per kilogram which is almost three times that of lithium Cobalt oxide batteries is approximately 980 WS per kilogram in theory we should be able to store around 5 to 10 times the amount of energy in current lion batteries in a future Sabers battery of the same weight remember more energy density is better for Mobility like EVS electric planes not as critical for your phone although if your phone lasted 2 days instead of one I'd take that but sulfur alone is a bad ionic conductor adding selenium to the mix increases conductivity so we can get more power but there's a trade-off because it lowers the energy density so team and NASA worked hard to optimize the ratio of the two to balance energy density and power density energy density is just how much energy it has so if you have a 1 Kow hour battery you can run 1 kilowatt for 1 hour that's the energy but that 1 kilowatt is how much power density it has how high of an output could you put out in terms of current so you need to have both in terms of highs scale applications like aircraft the holy graphine acts as a scaffold that does two things it makes the cathode electrically conductive because graphine is a great conductor and it lets us compress the cathode into a thin and stable layer without adding a polymer binder which is typically used in every other solid state cathode making it heavier but the key component of the whole system is a solid state electrolyte obviously Sabers batteries use one of two lithium Rich solid electrolytes lgps which is highly conductive and allows high power batteries the problem is that it has geranium which costs 10 times more than silver because it's hard to extract this makes this electrolyte expensive and possibly only viable for space missions where price isn't that important and two arite which is far cheaper but it's also less conductive so you get less power these electrolytes exchange lithium ions moving through the crystal lattice from one electrode to the other the best thing about this Solid State Design is it allows for something called bipolar stacking bipolar stacking means that we can stack cells back to back with both electrodes sandwiching the same current collector foil this is important because it lets us connect the battery cells in series Without external wiring and without individual housings for each cell it's a little bit nerdy but bear with us we can do this with lithium on battery cells too but it requires high quality coating technology accurate balancing and advanced thermal management this is why you see ev battery packs made in separate individually house cells that then have to be connected through external conductors welded onto the positive and negative electrodes this has so many benefits it reduces the weight and volume of the battery pack it increases the system voltage it also makes it easier to layer these cells in different geometries and possibly adapt to the shape or Contour of an aircraft for example it's easy to see why Dr vigano and his team at Nasa are so excited about their breakthrough the Sabers program has implications beyond the field of Aviation they could also benefit the electric vehicle industry offering a safer and more efficient alternative to lithium ion batteries air taxi services and commercial airlines could also benefit from these batteries due to their higher energy density and quick charging capabilities we can also use them on space missions to power Rovers and space suits and space stations and everything else but after looking at the numbers the one question on my mind is can the saber battery realistically power a commercial jetliner and really help Electrify Long Hall air travel and the answer will surprise you we set out to find the specs of the most popular commercial aircraft in the world the Boeing 737 in production since 1968 with a total of 10,877 units sold to see what it would look like to replace its engines in fuel with electric motors and Sabers batteries this will be found in the latest model the 737 Max 7 so together the 737s two engines and fuel which we have to replace weighs 57,7 60 lb and it produces a peak power output of 30 megaw let's see how that would work out for our Sabers batteries we consider the amount of fuel its energy density about 12,000 WS per kilogram and the efficiency of the leap engines and the efficiency of the best electric motors and power transmission units we could find to calculate the amount of energy we'd need to store in batteries for an equivalent performance at saber's 500 W hours per kilogram rating we'd need a mass of 188,000 kg and that's not counting the motors the best possible alternative for a high power electric motor is mit's Prototype 1 megawatt electric motor which weighs only 57.4 kg for a specific power power of 17 KW per kog remember we need at least 30 megaw of engine power for takeoff which means 30 MIT engines weighing roughly 1,722 kg so the weight of the system would be roughly 190,000 kg that's seven times the weight we are replacing and over twice the maximum takeoff weight so realistically the Sabers battery won't help us replace the popular 737 with an equivalent electric version at least not with the same 4,000 Mi of range so no we're not going to be doing transpacific flights with the saers battery but this doesn't mean it won't make a significant impact on the airline industry we don't really need 4,000 nautical mile range most of the time in fact 90% of all passenger flights are less than 1500 nautical miles the largest proportion of flights are around 500 nautical miles long so we could get away with reducing the range to 17th or approximately 550 nautical miles this won't reduce the mass of the batteries to exactly 17th but it puts it well below the maximum takeoff weight 500 nautical miles will get you from New York to the eastern border of Ohio Western Michigan North Carolina and to the tip of Maine or it could also get you from San Francisco to most of Oregon Nevada and parts of Arizona so as it stands combined with a suitable motor like the MIT 1 megawatt prototype the sabr battery could offer enough performance to Electrify a very large portion of commercial flights at least the shorter legs of them in the mean time it'll be great to see these batteries and EVS sooner than later just imagine a battery that's lighter cheaper holds more energy and that will never catch fire even if you crash but just we're getting excited about this breakthrough Battery tech we started finding some major drawbacks as well the solidate battery's biggest enemy is power density these batteries generally suffer from low charg and discharge rates limiting the amount of power we can extract or put back in and now this is a major problem for aircraft that need an immense amount of power for takeoff and in the case of vtols for hovering it's like having a massive tank of water connected to a tiny hose when you need to put out a fire you have all the capacity in the world you just can't get it out fast enough researchers claim that the new battery has an overall 50-fold increase in power density compared to their earlier prototypes but just how much power is that NASA doesn't say or at least we couldn't find that particular piece of data and it kind of raises a red flag right but we wouldn't be too bit of viny if we didn't at least try to come up with an educated guess based on as's data we know that the sa's battery can charge at a rate of at least 1 C this means that it would be fully charged from 0 to 100% in 1 hour this puts a saver's specific power density at 500 watts per kilogram for comparison a Tesla 4680 cell which weighs 355 G and holds about 97 wat hours of energy can be charged and discharged in about 15 minutes a rate of 4 C this means that it has a specific power density of approximately 1100 W hours per kilogram over twice that of the saber's battery so Sabers has roughly half the power density of one of the best lithium on batteries in the market which is nothing to scoff at considering that most older solidate batteries had much less than a tenth of that power another major drawback of the sulfur selenium battery chemistry is something called polysulfide shuttling which reduces cycle life significantly this happens when the sulfur in the cathode moves or shuttles through the electrolyte and to the anode a salt electrolyte is supposed to avoid this completely but I found at least one published paper where the authors prove that it can still happen even with solid electrolytes now this can limit the cycle life of the saber's battery to only a couple hundred cycles that means charge and discharge only a couple hundred times low cycle life means the battery dies sooner and you have to replace it more frequently adding more maintenance and downtime costs now these extra costs are a huge problem especially in the airline industry that already operates with super tight margins of as little as 1 to 2% if NASA doesn't get this fixed I doubt any aircraft manufacturer would take this seriously and build electric Jets anytime soon and if they do I doubt any Airline would buy it there is a silver lining though because NASA isn't the only one developing solid state batteries Toyota the world's biggest car manufacturer by volume unveiled the development of a nextg solid state battery that will hit the commercial scale and Market by 2025 Toyota claims the battery can add 745 Mi of range to their future EVs and charge fully in 10 minutes at a rate of 6C which is kind of nuts however they didn't give any specific details about it so we'll have to wait and see they plan to integrate into their lineup of hybrids and plug-in hybrids by 2025 and into their all electric vehicles by as early as 2026 now that's just 3 years away and we'll see because they've dragged their feet until now always with this promise of a future EV with solid state batteries but time will tell several other companies like Nissan are also working on solidate batteries but the most promising in my opinion is lighten which is setting itself up to mass produce a lithium sulfur Sol State Battery very similar to NASA's Sabers concept this battery is the brainchild of linton's Chief Battery Technology officer Selena molac who is famous for developing batteries for Tesla while the company launched the model S model X model 3 power wall and power pack products she then joined Uber as director of battery engineering and then went on to Panasonic energy which produces batteries for Tesla and she later joined quantumscape another solid estate battery player except for Tesla where she worked for six years she's been jumping from company to company every year and a half give or take now she works at lion lighton claims at maturity their battery will have an energy density of 600 W hours per kilogram and 800 wat hours per liter and costs less than $60 a kilowatt hour that's almost a third of today's average lithium ion battery prices at the Pack level which cost $151 per kilowatt hour we'll have to wait and see if they live up to their claims or if Selena leaves before that happen she's already been there for a year and a half so who knows anyways this is one of those things that everybody is trying to develop and there's a reason there's so much promise behind the lithium ion battery especially when you remove the electrolyte and go solid state now Aviation still is a bit of a stretch admittedly but imagine a car that goes twice as far right with the same pack and everything else now if we can get the economics and the prices down the safety reliability longevity all together this is one of those home run things this is one of those watershed moments and it's why everybody's working on it I'm so relieved and so happy to know that NASA is one of them so what did you think how excited are you about Sol State batteries and how important is NASA in this game as we mentioned the the video there are a ton of things in our lives that NASA is responsible for all right so we thought that was cool check out this video next and until next week I'm Rick t d Vinci thank you so much for watching

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Channel: Two Bit da Vinci

Views: 1,087,023

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Keywords: two bit da vinci, solid state battery, nasa solid state battery, nasa sabers battery, nasa solid-state battery, nasa sulfur selenium battery, nasa space battery, NASA's New Solid State Battery Can REVOLUTIONIZE Travel, sulfur selenium battery, sulfur selenium battery nasa, sulfur selenium, NASA Just Made a Solid State Battery - Perfect Battery?, NASA Just Made a Solid State Battery - Gamechanger?, nasa solid state, Why NASA is Building a Solid State Battery

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Length: 20min 11sec (1211 seconds)

Published: Sat Oct 21 2023