Are These Batteries The Future Of Energy Storage?

So what batteries do you think have a good shot? Any you’d add to this list? See why hiring doesn’t have to be difficult - when you try ZipRecruiter for free at www.ziprecruiter.com/UNDECIDED.
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One important thing missing in this video (and many videos from many sources about energy storage systems) is the *EFFICIENCY*. For instance, some of the grid-scale storage systems are only 30-50% efficient, loosing the rest to heat in some part of the process of charging, storing, or discharging. I think this is a metric that we simply can't ignore, as it has fundamental implications for their long term economic viability, payback time, and appropriate use-cases.

Aluminum Ion and Aluminum Air batteries are still the two I'm most interested in seeing develop. It feels like the wait for new battery types has been one of the longest in technology.

#1 Solid State 4:59
#2 Sodium 6:14
#3 Aluminum-Ion 7:33
#4 Niobium 8:43
#5 Lithium Sulfur 10:21

My uncle worked on battery technology for Dunlop here in Australia in the 1970s and 80s - it always frustrated him how slowly they made progress due to the relatively primitive materials science they had at the time. Sadly he is no longer with us but I often think about how excited he would be if he could see how things have progressed in the 2000s since NiMH (which is probably more of a nineties thing), then Lithium Ion arrived. Despite some of the challenges the modern world is throwing at us today it is great that there are still things to wonder at.

Big fan of this comparison type video, would love to see a similar one on grid scale energy storage.

Just wanted to let you know that I really appreciate the work you do and I really appreciate the fact that you called your channel undecided. I think the world could use more undecided people rather than actively picking at Black or White. Our world is full of Gray. Thanks for all you do.

Great video, something to point out on the Lithium Sulfer batteries is the C-Rate comparison. You mention that they "only" have a 0.5C rate, whereas in reality that is basically the same as the Li-ion. A 1C rate at 200WH/KG is the same as a 0.5 C rate of a 400WH/KG battery in terms of power delivery per density. So basically, a 1KG battery in either chemistry could potentially deliver 200 watts over an hour, which to me sounds very promising.

everyday, we see a new battery tech without change, i've been seeing this since 2005

Awesome! Made me feel confident that the scenario in 5 years will be vastly different (or at least at the brink of becoming so) with several innovations still to come. Which is something VERY much needed.

I'd love to see more on recycling or environmental impact in general and fire/explosion risks. Safe energy storage is one of my main concerns, next to being able to properly recycle batteries.
As you mentioned, there is no battery to rule them all. A smaller capacity EV battery that can be charged super fast (like the Al-ion at 6C) means more charge cycles on the road but with the same energy demands as a double size 3C battery. Even if that Al-ion battery last half as long as traditional EV batteries but can be recycled properly (and does not cost as much) then this is a great solution for a lot of EVs.

Love this type of video. Please make them every once in a while to keep us updated!

Perfect timing Matt! Always doing the research I am too lazy to do! Best science reporter on youtube!

great stuff, i'm surprised some of these are so close to commercial use, obviously there might be some delays but it really feels like the next couple of years are going to see a lot of exciting stuff..
something like 5 years is really not _that_ long :) also having more options for battery tech will reduce the pressure on any one technology, like we have for lithium today, so that's only a good thing i think

I love the breakdown as the number of innovations is mind-boggling and it's hard to imagine what lab innovations are actually going into commercialization. It would be interesting to have some more statistics compared though. Like expected $/KWH, recyclability of the batteries and usage of critical materials as these might have a significant impact on the implementation of these batteries as well (I do understand that it might take too much time and resources to procure those stats though).
Thanks for the great video.

Thank you, Matt, for providing this comparison list. It is much appreciated.

*"Lithium-ion replacement? Great new battery tech coming soon!"* Sorry, but we've walked past this same tree a dozen times and the thrill is gone. Wake me when lithium-ion has _been_ replaced.

Thanks Matt. Always enjoy your videos and hi tech news in general. My favorite is aluminum graphene one. It should be easiest to make, cheapest to produce and 100% recyclable (at least in theory). Almost too perfect to be true.
Could you also look into Exro Technologies and their new type of electric engine for us. Seems to have a great potential to save 5 to 50% of battery power depending on use. Substitutes need for multiple engines in EV or need for a transition. Also it simplifies drive train and reduces cost of EV to manufacture. It also comes with smart electronic coil drive/converter which enables charging EV directly from any electrical source. They also claim that their coil drive can manage Li-ion batteries to charge more efficiently on every cell level prolonging life and making them safer to use.
Looking forward to your next video.
Cheers

Hey Matt, I think an interesting topic for a video would be the toroidal propellers currently being tested/manufactured at MIT and Sharrow given how they have so many potential applications across so many different markets.

Awesome.
It’s fun to hear about the other techs that r being worked on. Thank you

Great video, it would be amazing to see the comparison focus on grid scale batteries recap too, like sand battery, brick battery, molten salt battery vs Li-ion

Hi. You touched on the vehicle charging issue briefly. This is one of the big elephants in the room. I'd like to hear some more discussion on the huge infrastructure limitations that apply fairly universally. As an exercise use a low "C" charge rate of 5C (12 minutes) to charge a 60kWh EV battery. Now multiply that by 10 cars at the charging station at once. The power being drawn from the grid is enormous. I've worked in the electrical industry for over 30 years and know there's decades of upgrades ahead of us and we're already way behind. Don't get me wrong. I love EV's. There's a lot of work to be done on the entire electrical chain in addition to battery development. Most of which seems to be getting put in the too hard basket.

Thanks for quick updates, I'm really excited to see what future will unfold.
imo top 3 contender which we'll see soon are Solid state, Aluminum ion battery (for Ev, and smaller electronics), And Sodium batteries (for home/grid purposes).

I really appreciate this video and all you do, Matt. So clear! In fact, I've watched dozens of your videos and this is the first time I'm going to request more clarity. Please, when you do a list video, before going into each item, at the end of the intro, say, "The five battery technologies I am reviewing today are" ...
Would also love to see the comparison expanded to include things like environmentally friendly source materials that you mention in other videos, and a full comparison chart either in the video or available for download. And a video segment for each battery type even better.
Just thoughts to make a great channel even better!

Great video with clear simple comparisons. It would have been a lot more helpful to see cost if that information was available

Great overview. I've been in the Li-Ion battery industry for over 10 years now. I'm not sure what to think about solid state batteries. They have been "a few years from market" since about 2010. I've started to think of it like nuclear fusion. Also, an interesting thing is electrode specific energy as measured in the laboratory does not translate well to system energy density (volumetric or gravimetric). Many exotic chemistries need extra systems for thermal regulation, electrolyte circulation or a pressurized air vessel. By the time a functional pack is assembled all the energy density gains at the electrode level disappear with these added components. There is no free lunch with physics. I believe we will be seeing NMC, NCA, and LFP chemistries for a lot longer than battery optimists want admit 🙂

Thank you!!! We needed an update on the "top five" batteries even if it's subjective & changing almost daily. Greatly appreciated! Maybe consider a regular (quarterly maybe?) part of the format?

Always an interesting update, thanks

Great to see improvements.. I would be really interested in all those implementation on grid scale batteries that are already operational or in the phase of executing. These cases would be interesting to pitch to the company I work for to implement them ourselves. (we kinda use a lot of energy.)

Good to hear that the arrival dates are almost there, having in mind hearing of these tech several years ago and finding out that it will take like 5 years to reach the market.

Thank you for the quick overview, Matt and Undecided team!!
In terms of most capable battery systems, I’m interested in learning about the ‘small stationary’ class we could think of as home energy storage, esp when trying to get close to off-grid, where renewable energy can be stored for longer to provide >1-2 days home energy and nearly eliminate intermittency as an issue for powering a home. I haven’t seen much around flow or other non-Li tech batteries for home energy storage. Nearly all of them are (rightly) focussed on business -> industry scale, in part due to space requirements. Looking to see if any flow/plating battery companies are working in the home / small business scale.
Thanks again for your persistent and detailed interest in energy storage!!

Matt...very nice video. Thanks for sharing.

I imagine the physical density of these battery types varies as well, so energy/volume might be a good comparison attribute to highlight in addition to energy/mass. Volume matters.

Great video again. Makes me think-what more could a person ask for. My thoughts run 2 directions: First toward EV uses for possible investment purposes and second toward Home Power storage, which is personal to me because of local grid power outages. We live in a new age of inventing/engineering on both micro and macro scale. Please keep up the good work.

A year ago I swapped out my Lead-Acid for Lithium Iron Phosphate 100 amp batteries in my simple off grid home solar. Manufactured by Chins, (there are others also) they are a HUGE improvement in holding charge and charging speed at a cost very near Lead-Acid. Light weight , compact and available on Amazon. I'm now in off-grid heaven.

It's not technically a sealed battery, but I think vanadium fuel cells (aka flow batteries) are borderline criminally underexplored for grid scale storage, given that they've got far longer cycle lives than lithium based chemistries and their primary disadvantage is weight, not to mention that recycling of the electrolyte, the bit that's scarce in lithium cells, is trivial in vanadium based systems because it's a completely separate liquid that can be just drained off to allow only the fuel cell module to be replaced.

I think sodium ion will be a game changer in both grid and home stationary storage. What I have read has them at 30% of the cost of NMC, so figure a powerwall or Generac PWRcell for $5,000 instead of $15,000.
A lot more people could get home storage, including lower income households with subsidies or grants.
They could do this even before installing solar and use them for arbitrage reducing peak demand on the grid.

Excellent work.
The comparison with lithium was easy to make sense.

Thank you, always way ahead in you giving expert knowledge, so well put it together. Cool video's.
Cheers

For my small off-grid power system, the sodium-ion battery looks promising to me, especially with a potentially lower price tag and environmental footprint than lithium. And with the manufacturer being in Wales where I live, it's double lower footprint with short travel. I hope they are ready soon. My old lead acid batteries are close to dead.

Fabulous content. Really appreciate this comparative walk-through of various battery architectures. Of these, I've heard quite promising specs from Lyten's research in Li-S battery cells, which as you mentioned have superb energy density. I've heard Lyten state they see a pathway to 900w/kg and $80/kw, with the kicker being that it's a practically non-flammable chemistry and operates in a -40 to ~160C environment. Obviously if this verifies, and it's commercially scalable, it's a game-changer, and spells the almost immediate demise of any EV transition resistance. But I believe the much larger point is that battery cell R&D is in widespread, full-swing, and we're barely in the first inning. There is much reason to be optimistic.

I'd love to see you cover all of them, make it a series. Personally I'm bullish on aluminum-graphene and iron-flow batteries but your spot on about there's no battery that will replace all others. Since GMG's aluminum-graphene batteries are rated at 60c-70c, I think they could be used very successfully at charging stations to prevent sudden grid loading during heavy use and speed-up turnover times. Iron-flow is a great answer to any NIMBY sentiments and has basically no down-sides for its intended role of long duration, stationary power supply and most importantly, it's a product you can buy right now.

A great summary, thank you.

My focus is home energy storage which carries over to EV (eventually your EV will also provide home energy storage for backup power and for arbitrage scenarios). I think the technology with the greatest potential to change the world is the graphene super capacitor (similar to the Superbattery in your video). The technology is already here, but cost is still too high due to the manufacturing processes for graphene, but strides are being made in the right direction. The main advantage is the availability of raw materials (primarily aluminum and carbon), energy to weight ratio, and extremely fast rate of charge (minutes instead of hours). No more slave labor lithium or nickle mines. and recycling is easy. As for cycle life.....the potential is for 100,000 cycles. Only cold fusion will be better.

It is so annoying waiting year after year for these to change me to market. I bet in 3 years we will still be waiting.

Thanks for the video!

Great work, thank you!

Appreciate all this work on innovations and showing people a "brighter" future with all the gloom content these days that grabs attention faster... 🙏

I personally like the concept of the aluminum ion battery quick charging quickly charge an abundant of materials

Thks for informative podcast again and would be nice to see this top 5-10 batteries for larger stationary, non-ev if and when you get a moment.

Your intro is one of the most memorable ones i have ever heard! Ty for the interesting videos!

Please do a companion video on battery technologies that lend themselves to stationary applications.

I would love to see the stats from this video on a single table for comparison.

A comprehensive summary of the current contenders that are realistic for commercialization with the usual caveats you have pointed out Matt. As a retired Ph.D. material scientist, I had studied and followed many of these technologies for over 25 years and still have kept up with most if not all the ones with transformative potential.
I (and surely many of your viewers as well) would like to hear your thoughts on the MIT work on Donald Sadoway's molten metal batteries, especially for GRID or even commercial storage applications?

Thanks for the share.

Other metrics that _would be useful_ are *safety* and *cold weather* operation (such as mentioned only for niobium battery).
Lithium ion batteries have issues with runaway thermal effects, leading to fires, and exploding electronics and EV fires when damaged.
This is a very important issue for consumer goods, particularly in EV's where a slight performance loss would be acceptable for increased safety - consider how much of a car's weight and cost is already invested in safety.
And there's the much higher risk of having a car accident damaging the battery pack compared to crushing the battery of a tablet or smartphone. This would also be a concern of military users, as having batteries damaged by battle damage is certain to happen (you don't want a runaway battery fire on a military hybrid engine).
The other issue that particularly concerns EV's is cold weather performance, EV cars just don't do well in sub zero (Celsius) conditions. There's a lot of anecdotal reports of EV range being limited in Canada for example.
So the operating temperature when the battery starts getting degraded performance would be useful for comparisons.

Every week there is a new battery technology that is going to revolutionize the technology for over 20 years... But never comes out...
This is one of them...

Hi Matt, thanks for another great video, Alan

I'm not sure at what point I realized I wasn't at the Practical Engineering channel. It was actually pretty eerie. Fantastic, fantastic video.

I think sodium batteries for grid storage have huge potential. Cheap and cycle life will be king in this area.

One of my friends recently described to me the idea of "pumped storage hydropower" essentially being a mechanical form of a battery. Although it's not exactly a new concept I had never heard of it before and I thought the simplicity and practicality of it (in regions where it can be done of course since topography is a big factor) was actually really neat.

It's very interesting to learn about the recent development of batteries, because it somehow affects a broad field of technology and sectors. Great vid!

Love your channel Matt, would love to hear more about the Diamond battery.

I'd be interested in a video about the conceptual battery that John Goodenough came up with a few years back. The one that various other physicists believed to be physically impossible.

I like science/news videos like yours a lot. In my years I saw A LOT groundbreaking concepts for battery, energystorage and powerplants; not only here, but on many channels. Not one single item reached the public so far and I am honest here: I am tired of hearing about the 1000´s lithium-kobalt-iron-airFlow-water-sand-nickel-roboter-Pirates-from-outta-space-battery technologie of the future. It´s cool that people work on solutions, but so far nothing came out of it besides the always-same-feeling videos, I can´t feel hype for there anymore

Thank you for the C rate explanation.

Matt your puns and dad jokes are just flowing today and you worked them in seamlessly. What a presentation.

"Batteries to keep an ion", this one has to be one of my favorite puns this year ^^
Who else?

Why did the charged ion go to the doctor? Because it was feeling a little negative.

Thank you fr making this video. You are correct it is too early to tell which of these 5 technologies will capture a significant market share of which battery technology use markets. But it is good to share the possibilities with everyone. Would you please, make a similar video for the 5 most promising long and short utility scale battery storage technologies? and/or What combinations will help balance and meet grid the demands of the grid of the future that will rely on solar, wind, hydro and geothermal?

Hey mate!! Thank you for all the valuable information you have been educating us with. I would like to get a recap about Graphene or Graphyne based batteries and where they lie in the commercialization phase? Thank you

Do any of these batteries solve the temperature problem (i.e., they lose 1/3rd of capacity when cold)???

I am still tickled pink that I have 2kwh of LiPO4 batteries in my little camper van when just a few years ago that would have required at least 8 times the weight using lead acid tech… not to mention the dramatic increase in discharge cycles. But I would totally accept twice the weight in sodium ion tech, especially with a 6C charge and discharge capacity. We truly live in amazing times.

Super! Thank you very much!

Great video! I think LFP and M3P are the next to make big impacts.

For EV's high C rate not only means charge time, but it also strongly impacts how powerful of a EV you get out of a given battery size. It'll mean you don't have to spring for the long range version of a car to get the couple seconds quicker 0-60. C rating is arguably the most important metric provided we have charging infrastructure. It enables super quick charging cars with small batteries that are still powerful. Small batteries means cheaper cars and charging time is probably one of the biggest drivers of range anxiety.

I'll believe it when I can buy it

Very interesting i learned a lot.

Thanks for the video! Sodium-ion battery looks interesting for a home battery application!

I think solving the Cobalt problem is more pressing than the Lithium problem. Similarly, Sulfur has a terrible extraction process, often having people with minimal safety gear harvest it from volcanism. Surprised you should have included Phosphate batteries since they are the only alternative outside the lab, and Tesla has suggested there will be better formulas for it. Of the five mentioned, Aluminium is the best option for Supply and Use though the reliance on Graphene has me concerned it'll have more of a Solid State timeline.

So many technologies have for "numerous decades" been very"close" to market! lol

Love this Jaunbee Goody-Noff guy, great dude

Thanks for great videos! Vanadium batteries although also grid scale I think is worth mentioning or perhaps a video?

Batteries are NOT typically rated at 1C, they are typically rated at 0.05C or the 20 hour discharge rate. Actual capacity drops, sometimes dramatically, with increasing discharge rate and many battery chemistries struggle at the 1C rate (like common primary alkaline) and you only get a fraction of the capacity you get if you discharge over a day. Good luck actually knowing this with only the manufactures data sheet because they are usually missing many key performance metrics.

C ratings for NMC were closer to that of LiFePo4. NMC will easily do 10C or more (temperature dependent).
Also LiFePo4 will do 20k cycles at reduced depth of discharge.
A hype bubble of vaporware battery tech

Great presentation Dad!!

Awesome view of all up coming tech. I use the old tech of AGM batteries. Also live on the Sunshine Coast hinterland in Queensland Australia. Should I utilities additional ventilation via air circulation to assist with cooling the batteries? Also I am interested in trialing new tech batteries and will contact local companies, to see if they are interested. Thanks for your coverage! 👍

Has Matt talked about Community Batteries yet?

I've been watching this show for a couple of years now, and I have yet to see just one thing you talk about hit the market. Just one thing. This show is FOS!

Do you put Lithium iron phosphate batteries in the same bucket as Lithium ion? Thanks for the deep dive into other resources.

How Enovix did not make it on the list is mind blowing. Would love to see it covered as it’s much further along the manufacturing and commercialization cycle.

I wil be keeping an 'ion' all potential new battery tech. Hard to predict which wil come out on top as one option may be a better solution for 1 niche area but a poor solution for another.
Better not to put all of one's eggs into 1 basket...

To be honest, I don't really care how much of in improvement these are. If they can't be produced and manufactured in an ethical and environmentally friendly way, there is no chance I'm going to buy them.

What about the diamond batteries? You featured these about a year ago, I am personally excited by these because of the benefits they may provide while helping to decrease the waste products we have to contain.

A someone working in the field: I kind of have a problem how you compare the new technologies to standard Li-Ion. For Li-Ion you show average values that an existing battery can have/keep all at the same time. For the new technologies you show ranges of values that have been demonstrated but in different cells. For example the solid state cells with very high energy density do not at the same time have the highes lifetime and high current capability.. The high values demonstrated in each subfield are not currently achievable while also having all of the other subfields in place. In individual subfield Li-Ion cells right know can achieve much higher values than depicted here albeit with the trade of in other fields. The new technologies have the same trade off.

Companies won't allow it. Battery failure is now the only reason to buy a new device

The humor on this channel is almost intolerable.

Man I remember watching videos like this in 2016 about how much better the technology will be in 2020. Hopefully it’s coming soon, I can’t wait for the day I have a phone that charges at 6c and an electric skateboard with 2kwh of battery in a small form factor

Great video, subbed i love batteries 2!, hopefully there will be a great one for drone/uavs get rid of fast 3~~4 minute flights and scream around for at least a good 40~60 minuts,i think that hobby would be a llot more popular.thank you for sharing.

This guy has been making these videos for years... Still no breakthroughs. Please stop making these videos.