The future of electric vehicles and solid state batteries

I need to read up a little more on this but it ‘appears’ that some of the claims on these devices don’t come up to scratch 

https://youtu.be/H45HXs4xXfA

​@BPLightlog This is definitely going to be an interesting topic to follow! There’s a lively debate happening online right now about it as you've pointed out. Just think about it, a battery with those specifications could be really versatile and might lead us to the next big leap in battery technology. We're starting to see the first vehicles start to hit the market with MG and some Chinese brands. 

It looks like the technology was emerging several years ago https://pv-magazine-usa.com/2022/08/31/us-startup-unveils-plug-and-play-solid-state-battery-for-residential-applications/

I’ve also been reading about a semi-solid state battery which presumably bridges the divide between the technologies.

https://m.arenaev.com/nio_is_ready_to_offer_worlds_first_semisolid_state_150_kwh_batteries-news-2043.php

And then there are salt batteries alongside other things which suggest that there should be alternatives to li-ion soon … the only thing as with other developments, it may not be the ‘best’ option that gets the most support 

Thank you ​@Chris_OVO for takling this subject. It is vast and already full of myths, misinformation and misunderstandings.

I’ll start of by discussing what ‘range anxiety’ could be and why it probably exists just as a state of mind rather that something that needs to be fixed.

It probably started off when people started moving from fossil fuelled cars to EVs and I can understand why this is. Back in the dim and distant past I used to drive a silver Peugeot 405 GRDT  which used to pull our trailer tent when we still had two of our children living with us (they used to call her Silver Lady). It would do 700 miles on one tank of diesel (without the trailer tent). Quite a lot of FF cars will do at least two thirds of that on a tank. Now move to the early EVs in 2013 like the Zoe 20 with a 22kWh battery and a maximum range of 100 miles in the summer and a usable range of 50 in the winter. Couple this to the fact that chargers were few and far between (but dirt cheap or even free to use - unbelievable now) and quite often unreliable leading to a number of incidents of being stranded. Then there was the charging time which was quite significant, taking an hour to add 60 miles. So range anxiety became a thing and it has stayed with us for over a decade and people quote it as the reason for wanting bigger and bigger batteries.

But technology moved on. CCS charging became the standard and now, if you stop every two or three hours for a break and buy a coffee, the car has added 120 miles before you have even got back to it and this is a car with a 65-75kWh lithium ion battery that fits perfectly well into a mid-sized hatch or SUV cross. There are a lot more high power chargers around now and they have got very reliable with contactless card payments. You don’t even need an App** with a phone signal or an RFID card. During the 120 mile journey you used about 35kWh of energy, about half the battery capacity so essentially the other half of the battery remains unused. But ‘range anxiety’ still exists because all the older generation remember their diesel used to do 700 miles on a tank and that’s what they want back. The fact that you never used the 700 mile range on a tank in one go is neither here nor there. I think it’s a sort of FOMO - Fear of missing out. So the solid state battery concept is fine but don’t know if they are going to be reliable or not and only time will tell you that. Very useable technologies already exist using Lithium Ion (higher energy density) or Lithium Iron Phosphate batteries (longer life, faster charging) to fit into normal sized cars giving an adequate range for a reasonable price.

Solid state batteries could take over in some premium cars or for HGVs but the current wet cell technology has matured with high quality, production at scale and costs that are decreasing.

** You still need an App at the moment to find charging station, Zapmap is very good, other apps are available. Even Google Maps has added  charging stations.

Peter

As mentioned above, solid-state batteries look to be the next leap forward for EV’s and the like but the development appears to be at an early stage.

From research, there are several ‘formats’ vying for supremacy and although Toyota have only recently joined the ranks of a full EV, they have used batteries in their hybrid vehicles for over 20 years, so could be a key player to watch.

The list of key possibilities looks something like:

1. Lithium metal SSBs - a direct replacement for the graphite anode in traditional lithium-ion cells, using pure lithium metal.
2. Sulphide SSBs - sulphide electrolytes allow very fast lithium-ion transport comparable to liquid electrolytes.
3. Oxide ceramic SSBs - Often made out of ceramic materials such as lithium lanthanum zirconium oxide (LLZO), oxide solid electrolytes are highly stable and resistant to chemical degradation.
4. Polymer SSBs - Polymer electrolytes use flexible plastic-like materials that conduct lithium ions through their molecular structure.
5. Halide SSBs - a newer class of solid-state materials that combine strong ionic conductivity with excellent electrochemical stability.
6. Thin film SSBs - built by depositing ultra-thin layers of solid electrolyte and electrode materials. Currently used in small devices such as medical implants and microelectronics.
7. Solid-state Lithium sulphur SSBs - made of a lithium metal anode and a sulphur cathode.

Ref: https://interestingengineering.com/transportation/solid-state-battery-technologies-of-the-future

One of the biggest issues for SSBs is their tendency to develop micro cracks during the charging process. Various other materials can be added like silver and lanthanum but this would impact production at scale and cost. However, battery science moves forwards and a significant discovery could be made that makes them mainstream products in the long term.

https://www.sciencedaily.com/releases/2026/01/260118064641.htm

Peter 

Not really meaniing to put a damper on things but once SSB's get reliable enough just watch the big AI server farms monopolise the supply as backup ‘battery farms’ so that there are none left for EV use.

It will be a bidding war between the AI farms and the vehicle manufacturers for who gets them.

Far fetched you might think?

Look at what has just happened with computer memory - AI farms have already snapped up the whole of next years supply from the major manufacturers, and are negotiating for the next 3 or 4 years production.

Prices of home (and business) computers and smartphones will be rocketing as the nanufacturers vie for whatever memory chips they can still get for their products.

https://investors.micron.com/news-releases/news-release-details/micron-announces-exit-crucial-consumer-business

I'm thinking that it won't be a problem. Given that BESS is not limited by space the same way as a car battery there are cheaper options like Vanadium flow batteries which are more easily scalable by adding tank volume. I see SSBs being a premium product to start off with a premium price which is not what BESS is about. The other thing is that AI farms will run at more or less constant power with a small amount of battery storage as a UPS in case of a generator fault. A number of proposed AI farms have given up waiting for a grid connection several years into the future and have decided to put in their own generating capacity based on diesel engines as they are the ones with the shortest delivery times. So much for Net Zero.

I agree with everything you said about memory chips and the same applies to high end graphics processors. I'm not sure when the prices are supposed to rise for smart phones though as I've just bought a brand new 6.7 inch moto e15 Android phone for just over £50 from John Lewis.