Amazing stuff.
Betteridge’s law of headlines… “Any headline that ends in a question mark can be answered by the word no.”
100% the reason I didn’t even click it, thanks!
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Sorry, it still has a lot of improvements to be done.
I don’t get it. For the average consumer, EVs as they exist right now are fine. Charging is generally 20 mins every 2-3 hours and only on road trips. Charging an EV at home is a trivial technical challenge. I understand that there aren’t chargers on street corners, but vehicles are rarely parked more than 20 feet from some kind of electrical service.
The idea of shipping liquid fuel in trucks and dispensing it out of hoses at special fuel stores is just silly. Rolling out that kind of infrastructure is unnecessary, and hydrogen has already showed that it doesn’t work. We only did it with gasoline because there was no other way.
I can see liquid fuel being useful in certain applications, but for the typical consumer, BEVs are the way to go.
For the average consumer most EVs are too expensive. The batteries probably aren’t going to get much cheaper due to the rarity and expense of lithium. Finding a better battery tech could make the whole idea of mass electric car ownership make sense. I do wish people would stop caring about the range issue so much tho. Just charge the battery every night and you’ll almost never need more then 80 miles of range
I hope we drop the idea of mass car ownership tho. Effective mass public transit and micro mobility seems like a much safer and more efficient direction to go
Doubtful this will plan out tho. These articles are basically just corporate press releases. A couple of these battery techs might pan out and work at scale
Any base on those claims that batteries aren’t going to get cheaper? They have been for 15 years. There is still progress to be made. There are LFP that get rod of cobalt. There are sodium batteries in testing that will reduce lithium demand.
Their claim about lithium being rare is nonsense as well. There’s no lithium shortage, there’s more a shortage of refineries and battery packaging plants (which means by building more, batteries will continue getting cheaper) and other rare earth metals, which is more of an issue, but like you say, the harder to source ones are being phased out of battery design.
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Batteries almost certainly will get cheaper. Lithium isn’t particularly rare. There are sources where it isn’t economical to extract it currently. That’s what “reserves” measure: a source that is economical to extract right now.
We tend to find new ways to extract minerals, which expands our reserves. Happens all the time, and lithium is no exception. The big one right now is the Salton Sea and seawater extraction in general.
There’s also an interesting (string-based method)[https://engineering.princeton.edu/news/2023/09/07/revolutionizing-lithium-production-string] that could bring costs down and avoid the large pools of water that cause environmental damage and high water usage of current methods. It still needs to be proven at scale, however. I usually don’t like to focus on any singular advancement; battery tech advances by trying 100 things, and 10 of them are practical at scale. This one does look promising, though.
The only place I see liquid fuel being used is in commercial transportation, particularly in shipping and rail. Anhydrous ammonia would be perfect for shipping, and a nightmare anywhere else. That shit will fucking kill you in an instant, and those who survive just wish they were dead.
So it should only be used in highly regulated professional settings.
That said, it’s still a wonderful fuel option for those settings.
This electrolyte swaps shit? I see it as an attempt to reuse all that gas station infrastructure all over the place.
EV chargers are all over as well these days, but they’re still not anything near as ubiquitous and gas stations.
Owners of gas stations figured out a long time ago that attaching a convenience store to the business was a good idea, I think they’ll adapt to people hanging out for twenty minutes pretty well.
I expect we’ll see lots of charging stations off the highway become a Chuky Cheese, with arcade games and rigged claw machines with shitty prizes.
Gas stations around me are installing charging stations wherever they have room to do so. But I live in area with lots of baby boomers who have bought Teslas and Rivians. There is a group of 9 charging stations in the middle of strip mall parking lot a couple miles away as well.
It’s because people have this mindset that they might need to travel 600+kms twice a year, therefore they need a 700km range BEV because Despite 99% of their car usage is sub 200km ( and 90% is sub 100) it is somehow prudent to carry all that extra battery material and weight around unused
I think hydrogen makes sense in a few applications namely trucking and long range cars for the few who need it, though I would say it’s probably better to invest heavily in trains and handle most shipping with trains then put the stuff on trucks for the last 50kms and stuff
Hydrogen is also important in construction when utilities aren’t typically present.
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Then what about trucking? Lithium is not nearly as energy dense, weighs a lot, and does take a significant longer time to charge than a diesel to refuel. If you don’t believe me, look up the eCascadia by Frightliner. They are probably the current best option if you wanted a heavy electric truck, but they only get to around 200 miles with a load (for reference, a standard turbo diesel one would go around 600-800 miles and only take 30 min to refuel).
Currently in trucking, I’ve found that everyone kinda laughs at the idea of electrification (except on medium duty, that wouldn’t be too hard, just overly expensive). Current electric motors are fine, it’s just that the energy storage is nowhere near what is needed for actual use.
Yes, for most basic ev consumers current lithium is fine from a usability perspective, but from a cost one this might provide a much more useful alternative (assuming the cost isn’t insane).
I can see liquid fuel being useful in certain applications, but for the typical consumer, BEVs are the way to go.
There’s got to be a significant amount of trucking going on that’s within a 100 mile radius, no? You’d have to charge more often than you’d have to refuel, but that seems like a problem worth offsetting to get the potential benefits of electrification.
That’s more medium duty, and yeah, that probably could be converted to electric fairly easily (albeit at a higher cost). I was mostly thinking about longer distance travel, where the main goal is the most amount of uptime and you can’t afford to park and charge for 3-4 hrs every 200 miles. And that is usually the most expensive model, with most getting less milage and/or taking longer to charge.
spoiler
I think the answer for longer distances is trains, which can be electrified without needing to carry batteries. Trucks burning fuel should really only be a thing to reach populations that are too small and remote to have a train stop.
Not disagreeing, but I live in the US and even if that became a focus of the government, it would take a decade or two to actually get most of the rail necessary.
Pretty much everything you said was said about passenger cars 15 years ago. Can’t fix every problem right away. as much as 85% of trucking is under 200 miles (by freight tonnage). This defeatist mentality of ‘it won’t work for this application, or this application, it’ll never change’ will always fail as technology and engineering improves.
The Tesla semi proved that fully loaded 450+ mi trucking is not only possible but better in every way, Pepsi is eager to incorporate them and Walmart too. Here’s the trick, Walmart and other companies doesn’t give a shit about charge times as long as it’s manageable, if it ends up saving even a dollar per freight delivery, they will switch. If it never improved and legit took 4 hours per 200 miles, companies will set up relay trucking. Trucking itself will change if technology can’t. It’s always about money, charge times only bother the driver
The idea of shipping liquid fuel in trucks and dispensing it out of hoses at special fuel stores is just silly.
I don’t necessarily disagree with that but I hope you see that this type of infrastructure is exactly what we currently have and have proven to work.
It wouldn’t be that stupid to reuse an existing infrastructure that is already built. The issue with our current fuel infrastructure is that it is moving fossil fuel.
What I don’t get is how gasoline even has an infrastructure. It’s delivered by trucks. If you replace the manufacture and dispensing with new equpement, what infrastructure are you left with? Trucks?
It all relates to the density of energy in fuel.
Fossil fuel is so energy dense you can get away with pretty much any way to distribute/dispense.
what infrastructure are you left with? Trucks?
Trucks and most importantly thousands of strategically located gas stations. Even if you distribute a different kind and less dense energy I would argue it still makes sense to have spread out stations all over the place.
If we want to keep using our existing roads and highways we will need those stations even if they distribute something entirely different.
I just want a half decent second hand EV that will do 120 miles, for a reasonable price.
I can buy an acceptable ICE car for £5k, and it’ll do that.
But at that price range, the only BEVs can get are shagged leafs that will do 50 miles on a good day.The really annoying thing, is that 95% of my journeys are sub 50 miles. But I’m not willing to spend more than half the journey time charging midway through.
I test drove a Leaf and honestly it felt bad brand new. I got range anxiety just taking it on the highway and back to the dealer.
So far, I think Tesla has a monopoly on practical EVs. Say what you will about the cars (or their leadership) but the charger network they built out and having ~150 miles of actual range is hard to beat in an existing product.
EVs are fairly new while ICE vehicles have been produced for 100 years. This is why you can get an ICE for $5k but currently not an EV.
Putting a charger on every street parking location will become disproportionately expensive.
Most vehicles stay parked for at least 12 hours a day. The average American vehicle is driven 35 miles a day. A standard 15A 120V outlet would do fine. They can also be set to only draw power during off peak hours when electricity is cheap and plentiful.
I think running a few dozen feet of wire is easier than inventing a new kind of fuel.
Most people don’t live in the US, also a lot of people don’t live in single family homes and park on the street. No garage means you need to install lots of on street chargers.
Which amount to basically extension cords with relays. All the tech for charging is already built into the vehicles. Most people could live happily with just 20A at 240V.
I don’t see how inventing and rolling out the infrastructure for an entirely new kind of fuel/energy storage tech is easier than just running some more wiring. If they charge at night when the office building/apartment/transit energy use is minimized, it won’t even put that much strain on the grid.
And you get to keep all the existing benefits for single family home people. Sprinkle in some vehicle to grid, and it gets even better.
No, it won’t. Chargers are already on every bloody street, they’re called lamp posts. You just need to retrofit a plug into them.
Apparently, no one read the article. The primary application of this was for the military. The article is based on research done by DARPA. For military use, lithium ion batteries have way too short of a lifespan and the charge times are too long. Also, they can catch fire and burn for a long time, probably a real problem in a military context.
Flow batteries can mitigate all these issues and they’re cheaper and lighter. They can be made from inexpensive materials that are more readily available than lithium.
Given these benefits, it seems obvious that consumer applications will take off. The original researchers see an opportunity here and that’s why they formed a company.
Your cited lithium ion “20 min” charge time is for super chargers only, and in many cases is actually more like 40-45 minutes. Also, super charging is bad for the battery. In all other cases, you’ll be using an L1 or L2 charger which will take anywhere from 8 hours to 72 hours to charge a vehicle.
And, eventually, the lithium ion battery will lose its range as the battery degrades, making the whole car as disposable as that 3-4 year old smartphone you had to toss because the battery can’t hold a charge anymore. Flow batteries will keep refuel times to the same as they are today, and the material can be recharged up to 10,000 times, a huge improvement over lithium ion. And, the lifespan of your car won’t be literally glued and bolted to the lifespan of your battery.
Why do people get hung up on the supercharging stop they would need to make 2-3 times a year and ignore the 40x a year they currently go out of their way to wait in line for cheap gas at Costco?
Also, there are Teslas with 250k miles and 90% range. The batteries can already outlast their vehicles, and finally, recycling batteries is possible and a lucrative business.
I have a minimum of eight ~500 mile drives I have to make in a year. I drive a plated and insured golf cart for most of my trips but theirs no way I’m tethering myself to a power cord when I can, with great confidence, pull over and fill my minivan in ~5 minutes wherever I’m at once I get to a quarter tank of fuel. I also end up with several trips a month where having a minivan is convenient as hell. I’d love to be able to reasonably jettison fossil fuels at some point so I don’t understand the criticism towards discovery, engineering, and evaluation of a broad spectrum of solutions and applications.
It has many benefits. Many. At least if article is correct. Doesn’t burn. It allows for energy storage which is huge when you take into the account renewable energy generation. It might even allow you to store surplus at home. It’s less weight which results in less consumption.
Also what makes you say that hydrogen failed. AFAIK perhaps for cars is not viable right now, but for bigger vehicles it might be very convenient.
Edit: also doesn’t require huge improvements of energy infrastructure.It seems to me that we’ll be living in a world with multiple solutions to the “fuel problem”. In a city environment, maybe the lithium solution will be the best way to go, but we can’t ignore that it isn’t scalable for other uses. It’s interesting to see how fossil fuels are powerful by the way they solve many problems at once; of course, after we built the insane infrastructure to support it.
We need every thing we got to beat climate change.
Technically, yes. Most of the time. Beyond that, no. It isn’t good enough for a great deal of people. Lithium batteries are hard to recycle, hard and expensive as hell to replace, give constantly diminishing returns as range goes down every year it’s owned, people in apartments can’t charge them without going to charge stations that are more expensive than gasoline, and range anxiety is very much a thing that prevents anyone from exclusively owning electric vehicles.
Transportable fluid that holds more density than lithium (which means vehicles won’t be so heavy which saves on a lot of issues) and doesn’t require a nationwide restructuring of the electrical grid system seems like a way better idea than adding an extra 1200 pounds of battery that will cost $12,000 to replace when it goes bad.
I only wonder if the liquid can be safely disposed of or recycled/sustained. Regardless, setting up a system to use this would take two decades to really implement and we should have solid state batteries before then that should get rid of quite a few of the several shortcomings of lithium batteries.
This article uses “nano” way too much for me to take it seriously. It is written like a marketing piece.
Nano desu
Flow batteries are great for long duration storage, but not good for high power delivery.
This means they will work far better as grid storage than as EV batteries.
The article is about advancements that are solving the density problem.
What is your source?
High power is a matter of scaling (and size/space constraints). To increase the power output, the membrane size can be increased or multiple power cells can be installed as explained in the article:
If you want to store more energy, just increase the size of the solution storage tanks or the concentration of the solutions. If you want to provide more power, just stack more cells on top of one another or add new stacks.
https://piped.video/watch?v=YyzQsVzKylE
Lithium batteries scale power and capacity at the same time. Flow batteries can scale power and capacity independently.
The advantage of flow batteries is that they can have enormous capacities without the added cost of upgrading the power, making it ideal for grid scale storage.
Even if this new flow battery reaches the energy density of a lithium battery, and can output sufficient power, it would still need to reach price parity to be competitive.
Lithium batteries are an ecological nightmare and I can’t wait for better technology
What makes a lithium iron phosphate battery an ecological nightmare?
If it still relies on mined lithium, it’s some pretty bad stuff. Come to find out mining isn’t super great for the environment.
Much of the lithium is mined in Australia or via salt brines in Chile.
It’s not worse environmentally than the other mined materials that go into a vehicle.
That doesn’t make it a good thing.
Ok so let’s drill into it further.
Lithium gets mined once and then enters a circular system where batteries can be recycled after 10+ years in service.
It doesn’t exist in isolation either. While lithium is mined, its competitors (oil, coal, gas) are too with significantly higher environmental costs. They’re also not reusable.
Zinc Bromide flow batteries look like a great idea for static energy storage but if you’re worried about mining, I have bad news.
Are lithium batteries getting recycled? Because there are millions of pounds of disposable vapes that just get fuckin yote directly into a landfill. Then they crack and leak PFAS into the ground water.
Large car batteries can become second life static energy storage before being completely recycled .
This is one of those instances where capitalism helps us out - there’s money to be made in old batteries.
Single use vapes are pretty damn disgusting all around TBH.
So we should continue mining single-use hydrocarbons because disposable vapes exist?
But it does mean it isn’t any worse as well. Plus lithium can be recycled.
Cobalt: https://earth.org/cobalt-mining/
There is zero cobalt in a lithium iron phosphate battery.
Is that the most commonly used type of batteries in EVs?
I’m not sure on the global percentage, but they’re becoming far more common. Most of the top selling EVs where I live (Tesla Model Y/3, BYD Atto 3, BYD Dolphin, MG ZS EV) all use lithium iron phosphate (LFP) batteries.
They have a somewhat lower energy density so they’ve been avoided, but they’re way safer and better eco wise to the point that they’re getting uptake
This is irrelevant. First, there are chemistries not using cobalt, as explained already. Second, elemental cobalt is infinitely recyclable as all elemental metals, thus we don’t need to mine that much more, just like we don’t mine as much iron ore as we did centuries ago (relative to overall consumption). Yes, we still mine a lot of iron ore, but we recycle a lot as well.
This cobalt must be mined first to be recycled later, and being infinity recyclable doesn’t mean it will be, for example if it’s cheaper to mine new cobalt instead of recycling.
It was already mined, it only needs to be recycled if we continue using old battery chemistries. Which is unlikely.
I’ve always hoped so. Finally deal with both range anxiety and charging time together.
That’d be cool.
Hydrogen solves that.
Hah, no. Storage and infrastructure are still non-existent. And low temperature operation is still an issue.
There are challenges, but Toyota is throwing their weight behind research on hydrogen ICE. Here’s a good summary and analysis video. Of course it’s not perfect, but they proved it can be made. Now it needs to be made more robust.
What Toyota is doing isn’t a good indicator. They’ve been at hydrogen for decades. And they are the single biggest laggard for decarbonizing transportation. That’s not even an opinion, that’s just facts about their lobbying and marketing. No amount of research will make hydrogen infrastructure appear.
Infrastructure comes following the demand. It’s not like there were gas stations before there were cars. On the other hand, I think it’s good they are investing money in different technologies. I think they realize whoever gets to the new solution first will reap benefits, kind of how Honda insisted on using 4-stroke engines in their dirt bikes while everyone else was pushing 2-stroke. When the 2-stroke ban came, everyone else struggled to switch while Honda had it perfected.
Toyota might be lobbying and pushing their solution, but as long as they are investing and solution is cleaner we benefit in the end. Certainly better than what oil-lobbyists are doing pushing the idea it’s not a big problem yet.
How do you drive demand? If there’s no infrastructure you can’t sell anything that relies on said infrastructure. How’s California’s Hydrogen Highway doing? Not good. Demand and infrastructure go hand in hand, and you can’t magically make one develop without the other. Thinking otherwise is merely wishful thinking.
Demand and infrastructure go hand in hand
This is what I meant, they drag each other.
make car battery big, use nano liquid, issue fixed?
That’s some crazy battery technology. This would greatly solve a lot of current issues.
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