It was flat-out corporate malpractice that he stuck with the hydrogen strategy for as long as he did. What a waste of time and money, and what an excellent way to fall far behind competitors for absolutely no reason. He should've been fired awhile ago.
Toyota is one of the most trusted brands across the world. Their cars have extremely high resale value and are generally known to have long usable lifespans. Hydrogen issue aside, they are (at least currently) not 'far behind' their competitors.
I'm talking about falling far behind competitors in EVs. Which they have. EVs are the cars of the future, and they're flailing around wasting time on hydrogen instead.
No way. Hydrogen cars are chemical. The trickiest part about an EV is the battery pack, and hydrogen cars don't have 'em. Plus all that investment into hydrogen fuel cells is 100% non-transferrable.
This is totally incorrect. A fuel cell is a type of electrochemical cell. A fuel cell car has an electric motor just like a conventional EV. We often use the terms “BEV” and “FCEV” to differentiate them.
FCEVs are chemical in the same sense that BEVs are, because a “fuel cell” is, like a battery cell, an electrochemical cell.
The only real difference is that the “fuel” and “waste” are inside a battery, but come from and go to the outside in a fuel cell, which means that an FCEV can be fueled (and exhausts) like an combustion engine vehcile, despite being fully electric.
Toyota has had the Prius (and other hybrid) models for a long time so they have competency in building electric motor plus battery pack powered vehicles. I don't think its going to take a long time to get full EV's coming from Toyota. EV's don't need any futuristic design or gimmicky features either so don't waste time trying to innovate there. Get a Corolla out that has a 200-250mi range with decent ways to manage/monitor power and they will likely outsell others.
> I don't think its going to take a long time to get full EV's coming from Toyota.
They're already a decade behind where they could've been. The main problem is not that it won't take them long to start, but that it's been so damn long already and they've wasted all that time and haven't even started in earnest yet. Market share takes time to earn and they've given competitors a huge lead for no real reason at all beyond their absurd fixation on hydrogen.
I guess I disagree about being a decade behind and them needing to "start". I'll agree that they are behind. If they take their current car designs and adapt them for 4 electric motors + larger battery pack and discard ICE then they might not be very far off time wise. Its not like they need to come up with electric motors or battery designs, those are mostly just solved problems. Supply chain of battery components is likely the critical path. Toyota shares many designs, parts, etc. across platforms so I think its less work than "starting" from a blank slate as you may intend.
I think Toyota is making a Solid-State Battery too, and putting millions into it. This means it won't ever explode, is what I gathered when I read about it.
My speculative hot take on the reason that Toyota did not jump on the EV bandwagon and stuck with PHEV/Hydrogen is that much of it's operations are financed indirectly via low cost Japanese bank loans encouraged by Japanese government. These loans probably have an underlying perhaps unspoken component which nudges them toward business models which employ Japanese workers.
The one thing that EVs require is an EV charger network to exist in the foreign countries that Toyota sells the cars to. Without an existing EV charger network, it becomes a chicken and the egg problem for Toyota since, as a Japanese company, it would likely face a difficult time getting financing to build EV charger networks in foreign countries.
Hydrogen fuel theoretically would just be an adaption of the existing petrol gas station infrastructure so the existing players/gas station networks would just need to switch over.
Now that ElectrifyAmerica is more "a thing", Toyota can start shifting strategies.
VW and Tesla/US car brands could move faster since they were required (VW) or had home court advantage and government support (Tesla/US car brands) to finance the US EV networks. The Korean autos switched earlier as they were probably more hungry and had less to lose on ICE than the Japanese incumbents.
There's also the game theoretical play that being the only major petrol based auto producer could lead to pricing power if the transition takes longer than expected.
While this is a common refrain, as driver on my 3rd EV “charging network needed” a bad, bad misunderstanding propagated by people who dont drive EVs.
I charge my EV at home. I’ve charged my EV on someone elses charge (because i needed it, not because I got a better parking space) maybe twice since i moved to an EV with a 180 mile range. Heck, even with my “first gen” EV with a 63 mile range, I charged at home 95ish percent of the time, and those days are behind us now.
$2k to run a 240v external outlet, $500 for a charge station, and you’re set. Apartment dwellers still have issues, but thats simply because govmt/demand hasnt insisted yet.
> The one thing that EVs require is an EV charger network to exist in the foreign countries that Toyota sells the cars to. Without an existing EV charger network, it becomes a chicken and the egg problem for Toyota since, as a Japanese company, it would likely face a difficult time getting financing to build EV charger networks in foreign countries.
This could be solved today by using Tesla's Supercharging network, or at least their NACS[0] connector in the North American market. I know that auto makers don't want to rely on each other for _reasons_ but siding with Tesla would give them an instant charging network and completely solve the problem in one go.
Interesting - yes going forward now that they seem committed to EV. That would be a pretty unique partnership - and require a lot of trust on the part of Toyota.
EVs are not a sustainable solution. It is just replacing a dependency on fossil fuels with battery related metals. All car companies will shift away from the EV and towards hydrogen at some point. The dumbest idea is thinking that nothing comes after battery cars.
> FYI, coal is nowhere near dead. In fact it had it's biggest year just last year.
Maybe globally because India/China, but the US has shed Gigawatts of coal capacity over the last two decades.
> It's most likely replacement is... natural gas.
Yeah.
> And if you replace "fusion" with "fission" it is a very sensible argument.
Like it or not, we are losing our ability to build fission plants (Google Vogtle if you’re not familiar) and the only way an Electricity CEO in 2023 should be single-mindedly thinking about fission is if they have some inside information that the government is going to subsidized the heck out of it.
Otherwise, they'll just be the CEO with unconstrained capex and higher prices (and an angry utilities commission that has a singular mission to cut the rate base to reduce said prices as much as possible)
Coal is nowhere near dead. Europe is increasing production right now. People have greatly exaggerated the death of fossil fuels. We are decades away from moving away from fossil fuels.
A lot of the opposition to nuclear fission is just bad environmentalism. Take that away and we'd be building hundreds of reactors right now. We can easily reduce construction cost if it wasn't for excessive regulation designed to make it expensive.
>Coal is nowhere near dead. Europe is increasing production right now. People have greatly exaggerated the death of fossil fuels. We are decades away from moving away from fossil fuels.
Again, Yeah.
>A lot of the opposition to nuclear fission is just bad environmentalism.
This is categorically wrong. A lot of the opposition to fission is that it is not cost competitive with natural gas. Again, please google Vogtle. It took $30bn and 15 years to add two gigawatts of generation capacity to our grid.
Meanwhile, Indeck Niles in Michigan took $1bn and 2 years to add one gigawatt.
>We can easily reduce construction cost if it wasn't for excessive regulation designed to make it expensive.
I'm going to need a citation on all of this. What regulation exactly caused Vogtle to cost $30bn? Was it the regulations that the site should be built to spec and not leak[0]?
>In August, the U.S. Nuclear Regulatory Commission found two sets of electrical cables meant to provide redundancy in Unit 3 weren’t properly separated. Earlier, Georgia Power had to repair a leak in Unit 3′s spent fuel pool
Just to be clear, the power from a nuclear reactor is very different than that of a wind or solar farm. Vogtle is 2GW of baseload power, and is comparable to significantly larger amount of renewable energy. It is also the result of decades of low investment into nuclear until expertise has retired and now we struggle to find the right people to build new reactors.
The type of problems that are reported at nuclear power plants are basically ignored at other plants. Most power plants don't have any real redundancy, nevermind the insane levels of redundancy requires at nuclear power plants. The plant would have easily ran with those issues, but we just refuse to take even the smallest risk.
> Just to be clear, the power from a nuclear reactor is very different than that of a wind or solar farm.
Yes. Forced outages are typically complete rather than partial. They're heavily correlated and last months. So storage or backup needs to be many weeks to make it reliable at even the 95% level. Much of the generation happens at night when industries have to assign expensive graveyard shifts to utilize it effectively. It's also so expensive that increasing coverage for a set power target by overprovision is prohibitive.
> It is also the result of decades of low investment into nuclear until expertise has retired and now we struggle to find the right people to build new reactors
This must have been why reactors completed in 1979 were on average so much more expensive than the ones finished before. And why prices have gone up almost every time the same design is built again.
> The plant would have easily ran with those issues, but we just refuse to take even the smallest risk.
I love this line where you crow about how safe it is out of one side of your mouth, then whine about how if it didn't have to be safe, it'd be cheap. Let's replace the 'excessive' regulatory requirements with removing the liability cap and see who lines up to provide insurance on an entire city.
Also the residents around kadapa or husab would love it if they could have some of this safety you're talking about.
That has a lot to do with how old many nuclear reactors are and that we have zero spare capacity much of time. People who are anti-nuclear have failed to realize how much of the problems are caused by rampant anti-nuclearism.
Again, we are constantly adding more and more requirements to nuclear reactors. Everything must have quadruple redundancy these days.
You forget that nuclear is the safest or form of energy that we have. The number of deaths from nuclear energy is remarkably small. Sure, we can still insist on insane levels of safety, but we should not then turn around and demonize the end result. If we insist on these regulations, then we should also insist that people be aware of what is driving these costs, and make it a positive thing.
> That has a lot to do with how old many nuclear reactors are and that we have zero spare capacity much of time. People who are anti-nuclear have failed to realize how much of the problems are caused by rampant anti-nuclearism.
When they were new and before the regulations they were on less than half the time. Another lie
> You forget that nuclear is the safest or form of energy that we have. The number of deaths from nuclear energy is remarkably small. Sure, we can still insist on insane levels of safety, but we should not then turn around and demonize the end result. If we insist on these regulations, then we should also insist that people be aware of what is driving these costs, and make it a positive thing.
There it is. Right on cue, after already being calledout for it.
You're demanding free insurance. The insurer gets to set the policy on likelihood to destroy a city. Stop crying or findyour own insurance.
Also this is a myth. Solar is now the safest by a factor of two. Then wind. You continue to lie about everything.
If you include all the deaths from mining waste dumping and lung cancer of uranium miners, eye witness reports of chernobyl liquidators rather than official ussr reports, and the hundreds of unremediated sites that are less than 1% of their final age, then hydro beats it too.
Your "just" there ignores the efficiency, pollution, and emissions aspects.
Going from gas to electric is slow.
If electric -> hydrogen offers fewer of the benefits beyond removing a dependency on battery metals over much-cleaner-already EVs, that transition will take even longer, if it happens.
I don't deny that EVs have issues that we will have to solve like recycling and reducing the amount of rare earth metals in them. But just saying Hydrogen fixes that glosses over the massive amount of problems that needs to be solved for hydrogen to be viable.
Short list and no nowhere near exhaustive list:
Extremely high pressures required to get sufficient energy density
Hydrogen embrittlement basically requiring expiration dates on tanks in vehicles
Inefficiency/cost of green methods for producing hydrogen
How to create cheap fueling stations like we have with gas stations
That isn't to say these problems are not solvable but we have been working on them a long time and haven't made a ton of progress. Meanwhile EVs have already been able to overcome most of the big hurdles. I think hydrogen has a possible future in aircraft because the issue of cost, maintenance, and special equipment for fueling is status quo for aircraft already.
People are just glossing over the problems of EVs while trumping up the problems of hydrogen. You'll end up with nearly unsolvable problems with EVs that will force you use hydrogen somewhere anyways.
Hydrogen has been mooted as an alternative fuel as long as I remember (40 odd years). The fact there is barely any Hydrogen infrastructure (and hence, barely any cars) by this point, while there are plenty of electric cars suggests there are a lot more problems with Hydrogen than you might imagine. Yes, there are problems with EVs. But they seem to work for the here and now, and are certainly better than staying with oil.
EVs are over 100 years old. They were an abandoned idea until environmentalism drove their readoption. Environmentalism will make other ignored ideas come back.
If you compare the range of a 25 year old EV with a new one, it's pretty obvious that technological advances played as much a role as "environmentalism." California wanted to phase out gas after the smog nightmare of the 80s, saw the cars got <100mile range, couldn't do it. Only now is it potentially practical.
Hydrogen has a ton of shortcomings still. Technology might improve some of those too, sure. But if 75%, say, of the most severe environmental impacts of cars are mitigated by EVs, leaving a much smaller-sized problem in their wake, the technological advancements will have to be proportionally even stronger and easier to overcome to make the market move on again. (Or if EVs never replace >80% of new gas vehicles or so... but if inertia against change is that strong, that's not a benefit for hydrogen advocates.)
Hydrogen cars from 40 years ago had the same problem. They were terrible cars with short ranges too. This has changed with newer technology.
The biggest advantage of hydrogen is that they also solve the most severe environmental consequences of conventional cars, just without creating new ones of their own. It is similar to how LED lightbulbs replaced CFLs, even though CFLs were seen as necessary to replace incandescent bulbs.
Just look at the development of RC cars, it's not environmentalism that brought up EVs, it's technical progress.
80's electric RC cars were slow and the battery ran out in 5 minutes. People who wanted power used ICE RC cars.
Then we got li-ion and LiFePo4 batteries and brushless engines. Now the cars are so fast that regular people need to use limiters when driving. You can get a electric RC car up to 80km/h with off the shelf parts easily.
Uh... How? You'd need an entirely new fuel system at a minimum, even if you could reuse the rest of the powertrain. And hydrogen tanks are a lot larger than a gas tank, so finding a place for it might be difficult!
Steel is very problematic. 90% comes from China. Proven reserves of iron will run out at some point and we'll need to find new ones. Smelting uses coal. Iron mining is environmentally destructive.
Amount in the crust is hardly relevant. After all there are trillions of tons of lithium etc. in the Earth's crust. Transition to a "hydrogen economy" would put unprecedented demand on existing sources. It's not realistic.
Hydrogen still requires a distribution network yah? The electric distribution network (electrical grid) is already here, and every building and house has a hose. Incrementally upgrading that infra seems light years better than building a hydrogen distribution network.
True, but it does work for now, with a small number of cars, and can be improved as that number grows. This isn't the case for Hydrogen (where can you fill up your hyrdogen car?)
What makes you believe the current gas network can be used for Hydrogen? I don't believe this is the case, but would be interested in seeing evidence to the contrary.
Neither of the ewe assertions are even remotely true.
The grid can handle overnight charging just fine, there's more than enough transmission and distribution capacity.
Natural gas pipelines can not be used with hydrogen without some as of yet undiscovered coating. Plus these pipelines are single use; are you going to stop all gas usage in all houses before we let people fill up at stations or homes?
We can do load balancing on the grid, it's proven and old tech. Smart grids handle it easily and you don't need an unicorn startup to cycle the car chargers to balance the grid load.
We can use exactly zero of the current gas distribution system for hydrogen. Hydrogen molecules are literally the smallest in the universe, we haven't invented a container where they won't escape. You can't just pour hydrogen into a gas station tank or transport it in a natural gas pipe.
Transporting hydrogen will always result in huge losses. Less huge if you transport it as a liquid, but then you need to transport it at -252 Celsius - which brings a whole new set of problems.
Transporting hydrogen is easier than transporting electricity on the large scale. A pipeline is both simpler and more scalable than wires after you get to a certain size.
I have three BEV chargers at my home now. i didnt need to change a thing to my “built in 2000 to code” home to do this, as it “came out of the box” w/ 200 amp service.
My chevy bolt will charge at 8a (conservative) or 12a (“fast”) at my preference. It takes maybe 3-4 hours over night to charge from my average driving day with a decent commute.
My car consumes, while charging for a few hours overnight, about the same amps as a good clothing iron or a beefy vacuum. If i wanted, i could delay charge so three EV charged overnight, never draeing power at the same time.
My next car will buffer power so solar cells can overcharge and supply back to the house. And it will be a backup power supply for storms and grid outages so I no longer need a standby generator.
Tell me again about how the grid isnt ready for my BEVs and why we should be pumping some liquid or gas into tanks?
For a charging outlet, electricity is arguably simpler. But that is not what I was talking about. I was referring to large scale distribution of energy. We're talking GWs and hundreds of miles here. In that case, it is easier to move around hydrogen.
It is the same reason why we have miles of natural gas pipelines sending NG to local NG turbines instead of a few big NG power plants with wires sending electricity everywhere.
Natural gas leaks from pipes, but it's "free" so we don't care.
Hydrogen we need to make using a resource intensive process, and it leaks from every single container ever made, because it's literally the smallest molecule in the universe. Hydrogen transport incurs so big losses that it's not feasible at a large scale [0].
To move an equal amount of energy, you need 4x many ships as LNG, because you lose 23% more during transport than LNG AND you need to transport it at -253C which is a whole another issue.
Hydrogen is a good energy storage medium, but it's not practical for transportation. It's a lot easier and cheaper to move the same amount of energy using the power grid.
The future of hydrogen is renewable energy storage, on location. Not transport.
Neither natural gas nor hydrogen leaks in appreciable amounts in pipelines. They do care about profits, and leaky pipes lose money.
You do not need 4x as many ships. You just need bigger tanks. Hydrogen is much lighter than LNG. Bigger tanks are not an issue. You're hearing straw-engineer arguments from those with a vested interest to BS about these issues.
The video I linked to was "Michael Liebreich’s Keynote Speech at World Hydrogen Congress 2022"
Why would the World Hydrogen Congress have a "vested interest to BS"?
The speaker is comparing a LNG ship to a prototype Kawasaki LH2 ship, with actual values for both.
What he's suggesting is that we transport ammonia instead of LH2, ammonia is a lot more stable to transport and can be converted to hydrogen at the destination.
I wish more people would realize that lithium battery production is still pretty nasty, especially in countries like China with minimal environmental regulations. Not to mention the electrical grid will take some significant investment (hopefully in renewable energy sources for this huge transition to make any sense) to be ready to accommodate such a huge increase in consumption.
A dependency on fossil fuels isn't a good thing, certainly not to the extent that we've developed, but I really don't think the answer is as clear cut as everybody treats it to be.
The comparable here is oil extraction. I have never seen any evidence that oil extraction is better for the environment than lithium mining.
The grid will require significant investment no matter what at this point. Many parts are nearing the end of their useful lifespan, being built more than 50 years ago. Renewables and electrified transport definitely add to it, but people are trying to pin the entire cost on those things which is just wrong.
> Even if we convert the grid to 100% renewables and get rid of fossil fuels, we will still need to mine for battery materials.
But we'll no longer need to extract and burn fossil fuels, which is where the vast majority of the environmental benefit comes from. You can't say "Aside from the main overwhelming benefit, it doesn't look so good"!
> But we'll no longer need to extract and burn fossil fuels, which is where the vast majority of the environmental benefit comes from.
You're conflating different things. Battery production does not mean we will automatically get 100% clean energy. Gasoline in cars accounts for like 15% of the US's fossil fuel usage.
Again, batteries are energy storage. Not energy production.
This idea that batteries --> clean energy --> All negatives of batteries must be ignored is disingenuous and wrong.
This shouldn't come as a surprise to you, but people advocating for the use of EVs to solve emissions problems are almost universally also arguing for lower emission sources of grid power, like solar/wind. The two go together like ducks and water.
Yeah, and they adopt batteries with all the same emotional attachment and they have for green energy. They consider a discussion of the problems with current battery tech as an attack on green energy itself.
It is very comparable in the realm of automobiles. A tank full of gas and a battery full of electrons provide the energy it takes move your car. Oil must be extracted, refined into gas, transported to a local station, and then stored in your gas tank. Even with no renewables on the grid, converting fossil fuels to electricity is more efficient than gas. Except that every year the grid shifts to more renewables.
Bottom line batteries/electricity generation do less ecological damage today than gas/gas tanks, and every year the gap will increase.
The nice thing about battery EVs is that 95% of what's there is completely indifferent to the kind of battery used. The charging infrastructure can remain exactly the same. Even the battery management system can be tweaked to handle the charge rates and thermal characteristics of almost any chemistry. Lithium isn't the only option. Anything that gets us away from combustion-based/pumped-fuel designs, which lack this flexibility, is a good thing.
One of the hardest parts about hydrogen is bootstrapping the infrastructure. You need new production facilities, pipelines, storage tanks, pumps, and probably a lot more. All of which need to handle hydrogen, an extremely flammable gas that likes to squeeze through any material you contain it in due to its tiny size. In terms of switching away from oil, the only options are biofuels (which have their own major issues) or electricity (which already has a distribution system across much of the world). If we run out of Lithium in the ground, we'll start recycling it a lot more efficiently. While mining isn't ideal, at least mining and using Lithium isn't causing climate change.
The fact you can charge you EV at home (from your own solar panels if you have then) is a massive added bonus that's going to be hard to convince people away from once its established.
Thinking about what comes after battery cars (assuming there's a Lithium shortage) - I'd be very surprised if Hydrogen can scale up; I think it's much more likely we move to other battery tech, or perhaps novel liquid fuels. Hydrogen was always a greenwashing ruse by petrolchem companies.
I don't think most people truly appreciate how difficult hydrogen is to work with. It is nothing like fossil fuels which can happily sit in a regular tank for extended periods of time and be fine.
Way too many people advocating for hydrogen vehicles seriously have an idea in their mind where they just pour hydrogen into a their current vehicle, and it'll still make the comforting brr-brr sounds they're used to.
They don't actually want a hydrogen vehicle, they just don't want an EV and use "hydrogen is coming Soon(tm)" as justification for it.
People have actually looked seriously at what a world of only EVs would look like. It is basically a disaster of unsustainable resource consumption. Hence the need for hydrogen cars. EV believers have their own misperceptions about what is a good idea and what isn't.
Like the one report that warned us that the earth didn't have enough lithium to electrify everything.
Turns out they calculated that we need, for some reason, enough batteries to store a full month's worth of global electricity production in batteries. No wonder they got the fancy headline :D
Should be noted that fuel cells are batteries. We can already eliminate this problem right away. But we must "wait" for future batteries for no reason at all.
No, fuel cells consume fuel; effectively they are oxidising it in order to make electricity directly. For a hydrogen fuel cell, you still need to add hydrogen when it runs out. Whereas a battery (in the accepted usage of the word) is self-contained - electricity can be pumped in to recharge it, but no fuel.
Fuel cells do not consume fuel. It converts hydrogen and oxygen into water. You can reconvert water back into hydrogen and oxygen. You can conceive of a fully closed-cycle system for this.
But it's not worth it, since you are just carrying a big tank of water for no reason. It is a smarter solution that a battery which does carry everything at all times.
There's only one element above lithium on the periodic table. If there's a replacement for lithium, it is hydrogen.
Most of what you say is not that different than what people said about batteries. Let's not forget that li-ion batteries are really hard to make and have their own major challenges, and for a long while seemed like a terrible idea. The story is basically repeating with anti-hydrogen arguments.
This includes the dumbest of them all: that it is just a conspiracy by oil companies. Last I checked, there is no carbon in hydrogen, and "novel liquid fuels" will imply adding carbon to it. So either it is not a conspiracy by the oil companies, or the oil companies were right all along.
Given your seeming misunderstanding of chemistry, I'm not going to debate any further, but for the sake of others reading, I'll point out that there are two elements above Lithium (Hydrogen and Helium), and that Lithium is a (solid at room temperature) metal makes all the difference. And the fact that Lithium not being burnt as a fuel like H2 (thus requiring fuel storage and refueling), but instead as part of a compound that is used for energy storage.
You are misreading my statement. There is literally only one element directly above lithium on the periodic table. I was not referring to atomic mass.
Hydrogen is not burned in a fuel cell. It works the same way as lithium does in an li-ion battery. However, you can use hydrogen in a combustion engine, also as a compound for energy storage. Also, "fuel storage and refueling" is a huge advantage because you don't need to worry about slow recharging. This is often seen as an advantage.
What argument do you think you're making here by referring to the layout of the periodic table?
You might rather refer to a color-coded periodic table which shows which elements are gases and which are solids at room temperature. That's a much more relevant concern than whatever you're trying to say.
The point is that any material below lithium on the periodic table will likely result in a lower energy density battery chemistry. If you want something fundamentally superior than li-ion, there's really only one option. Hence why any replacement for li-ion is likely to heavily emphasize hydrogen.
You mean like high density LFP/LMFP that is coming into mass production this year at 200-230 wh/kg? (aka the 350-400+ mile car) That require no cobalt/nickel?
You mean like sodium ion batteries that are coming into mass production this year at 150 wh/kg? (aka the 200-300 mile car) That don't even require lithium?
You mean like Lithium Sulfur batteries that are poised in five years to double or triple battery density?
Or you mean like the Sodium Sulfur batteries that will probably come a year or two after that which similarly double/triple NMC capacity but only require sodium and sulfur?
Your take is ten years old. High density LFP and good-enough density sodium ion is going to deliver a comprehensively cheaper car drivetrain than ICEs can deliver, and each year will only be worse and worse news for ICEs. I would predict by 2030 there will be 600 mile range EVs (real world, not WLTP) whose drivetrain component cost is 1/2 of an ICE.
We'll have to see what comes out of Toyota. They have the DNA of execution, efficiency, and engineering. It's hard to see if it is "too late", because EV transition is such a massive investment in vertically integrated manufacturing at this point, while carmakers outside of Tesla are so OEM focused. We'll see.
I had kind of assumed that Toyota would be asleep at the switch and a joke for another 2-3 years, this is a surprising development. The fact they were pushing hydrogen still last year in public and poo-pooing EVs, and given the ossification and malaise of large Japanese corporations, I assumed it would be status quo until substantial market share was lost.
Is this activist investors again, like BMW, VW, etc? Is that even a thing in Japanese megacorps?
You do realize that hydrogen has an effective energy density of ~1,000 Wh/kg? Even with the weight of tanks and fuel cells taken into account. Meanwhile, most of your listed battery chemistries haven’t been invented yet and may never exist.
All the hydrogen generation/splitting facilities (it all comes from methane, right oil company astroturfer?)
I forget, did you guys fix the various fundamental laws of thermodynamics so that you can get hydrogen from water at high efficiency? You know, water, that ultra-stable molecule? Or should we just ship the electricity over the existing grid rather than take 30-50% losses putting it into hydrogen, physically ship it with some new fangled hydrogen tank truck, and then get the energy out?
So how much energy do you use to GET to that 1000 wh/kg? Oh right, you'll really just get it from methane or tar sands or fracking or whatever. Right oil company executive.
All the hydrogen transport infrastructure. Does hydrogen like being in tanks? I forget. Does it basically leak from everything? Hydrogen is really stable, right?
All the hydrogen refuelling stations. Wait, is hydrogen a liquid? Oh, it's a gas? man, those'll be annoying to engineer. Right, bet that's a solved problem for Joe Q public.
All the fuel cells that last longer than 100,000 miles. I forget, did you fix that little platinum problem? Right, solved problem.
Here's the real kicker: what price are you targeting with hydrogen cars and infrastructure? It'll take, what, 10 years to get close to what the electrical grid and current recharging stations offer? I mean, we have EVs like NOW. Lots of them. Hyuuuuge factories. Does the "hydrogen economy" exist yet? Right, only if you use methane? Gotcha oil company dude.
I forget, can I slap some solar panels on my roof (especially those perovskite multijuntion ones that I hope come out in a few years) and directly use that to generate hydrogen for my hydrogen car? Oh, is that a bad idea? I should just use an EV?
Don't get me wrong, hydrogen has potential to be useful. Medium/long range aviation, really long haul shipping, really long haul trucking. You know, edge cases. You know, unless synth fuels become a thing.
So just to reiterate:
1) you have no factories for a mass production car
2) you have no green production of hydrogen
3) you have no transportation infrastructure
4) you have no pumps/refueling
5) it'll take, what 10-20 years to get to where EVs are right now?
While EVs:
1) have factories / in production
2) can use any generation source, just hook it to the grid.
3) transportation? You mean the grid? Or generation at home?
4) recharging stations, while yeah, not what gas stations are, they exist and are actively being built out
5) and just to reiterate, there's been production EVs for... 15 years now?
Your little hydrogen bus system in Japan? I almost guarantee that gets chucked once cheap EV buses hit the mainstream (they don't need to go far, they do lots of stop-go so regen, it would be really nice to charge them off the grid, they will be cheap/in mass production). I mean, if you're a city, would you like supported / non-bespoke cheaper-than-ICE buses with low maintenance cost, cheap repair, or some screwy hydrogen thing?
Industrial scale electrolyzers exist now and are being deployed. The rest of the your post is just attacking strawmen. None of those problems exist at the scale that you think they exist. For instance, fuel cells are already lasting tens of thousands of hours, so they are well past being durable enough for cars or other vehicles.
We are also not discussing the viability of EVs and hydrogen cars right now, but what will happen in the future. After all, the start of this conversation is about Toyota somehow missing the boat on EVs. But people are forgetting that EVs are not the final step in the evolution of cars.
In reality, people are just repeating similar claims against hydrogen vehicles as people in the past have against EVs. The problem is that EVs have their own fundamental weaknesses that will probably never be solved. Those weaknesses will eventually require an alternative, of which the most likely is hydrogen. In that case then, Toyota is not missing out on anything.
_Static_ fuel cells are lasting tens of thousands of hours. The big ones you use at factories.
The Toyota Mirai, which is the crown jewel hydrogen vehicle at the moment, has only 5000 hour life span on its fuel cell. You'd think they'd install one of those tens of thousands of hours one in it if they could?
That's utter nonsense. These things are rated at a specific power output. People have actually driven them to very high mileage and not seen such dramatic declines. Not to mention that these things degrade similar to batteries, with a slow reduction in power rather than sudden death.
> It is just replacing a dependency on fossil fuels with battery related metals. All car companies will shift away from the EV and towards hydrogen at some point.
You are aware that nearly all commercial hydrogen comes from fossil fuel extraction, yes?
Nearly all electricity comes from fossil fuels too (well, ignoring hydroelectric and nuclear). Renewables still make a small contribution to the grid, and 10 years it was tiny.
It's obviously just history repeating itself. People complain about current emissions while ignoring future emissions. In hydrogen's case, it is the same as electricity. It is as green as the source energy, which in the long run will be green.
> Nearly all electricity comes from fossil fuels too (well, ignoring hydroelectric and nuclear). Renewables still make a small contribution to the grid, and 10 years it was tiny
VRE has produced more world wide than Nuclear for several years now, and is increasing at roughly 1/4th of the cumulative size of the entire nuclear fleet every year.
Even in that case, it is only 2021 that it happened. So VRE has not exceed nuclear for "several years." You are guilty of your own accusation of constantly lying.
Also, Eastern nuclear power growth has displace Western nuclear shutdowns. So the total amount is in fact a plateau. I did not know that until now.
Ultimately, the main issue is still the problem of intermittency. Until it is solved, VRE is actually much less useful than it seems on a chart. Even in a scenario where it exceeds 100% of demand, there will still be huge shortages on certain days. Ironically, the best way of solving this is via hydrogen production, but VRE advocates despise that idea.
> Even in that case, it is only 2021 that it happened. So VRE has not exceed nuclear for "several years." You are guilty of your own accusation of constantly lying.
Last I checked it was almost a month into 2023, not part way through 2021 when the production had been higher for a whole year already.
> Also, Eastern nuclear power growth has displace Western nuclear shutdowns. So the total amount is in fact a plateau. I did not know that until now.
So you made up whatever you decided sounded good about today's producton?
> Ultimately, the main issue is still the problem of intermittency. Until it is solved, VRE is actually much less useful than it seems on a chart. Even in a scenario where it exceeds 100% of demand, there will still be huge shortages on certain days. Ironically, the best way of solving this is via hydrogen production, but VRE advocates despise that idea.
So you made up the stuff about the scope of production, doubled down on it when called out, and now you're making up stuff about intermittency. And finally you're trying to conflate rejection of hydrogen where it is appropriate with calling out your blatant fossil gas propaganda and shilling for hydrogen cars.
I am not a walking encyclopedia. But you are a troll for acting like this.
The point was that VRE is still a tiny part of the overall grid. It will stay like that for a long time to come. And the original point that hydrogen is some kind is scam for not being green enough right now is pure hypocrisy, because the grid is in a similar situation.
And you immediately ignored the relevant points before launching into ad hominem and spouting off a conspiracy theory. Ironically, proving my point about how VRE fans do not want hydrogen production even though it solves the biggest weakness of VRE. Proving that VRE fans are just trolls these days and have nothing of relevance to say.
The best you have is that I was slightly imprecise, I am happy to correct that to "around two years". You didn't need to be a walking encyclopaedia. You just needed to not state something if you didn't know it was true (this is called lying), and then not directly lie after looking up the correct answer and having it in front of you whilst citing the source that disagreed with you (this is called gaslighting).
> The point was that VRE is still a tiny part of the overall grid. It will stay like that for a long time to come.
13% and growing exponentially by 5% of the total yoy isn't tiny. And intermittency doesn't even impose a need for dispatch, interchange, or storage until it hits at least 75%.
> And the original point that hydrogen is some kind is scam for not being green enough right now is pure hypocrisy, because the grid is in a similar situation.
Burning hydrogen for transport or heating is a much worse plan than using electricity directly. On top of heat pumps existing, seasonal sensible heat storage has a higher volumetric energy density than hydrogen, electric elements are much more efficient than electrolysis + transport, and fuel cells + electrolizers are worse than batteries by pretty much every metric.
> And you immediately ignored the relevant points before launching into ad hominem and spouting off a conspiracy theory. Ironically, proving my point about how VRE fans do not want hydrogen production even though it solves the biggest weakness of VRE. Proving that VRE fans are just trolls these days and have nothing of relevance to say.
Again, you're trying to conflate rejection of shoe-horning grey hydrogen into nonsensicle places whilst pretending it's green with rejection of hydrogen.
So basically when you make a mistake, and the other person makes a mistake, it means that the other person is liar but you're just making a mistake. Got it.
This conversation is going to end here. You are simply not worth debating against. You're just a huge troll and are wasting everyone's time by acting like this.
Refering to a thing being true during four separate calendar years as 'several' is perfectly valid.
Similarly stating an outright falsehood with the source in front of you isn't a mistake, it's a lie. One that is part of the current fossil fuel and nuclear misinformation campaign.
You having a tantrum and cry bullying when your lies are pointed out doesn't make me a troll. Quite the opposite.
You're right. Mining 400kg of carbon, iron, and aluminium for a battery in a sodium ion car is prohibitive. Rather than replacing it with nickel, copper, noble metals, and rare earths in an electrolyser and fuel cell we should remove and shrink as many cars as we can by mass expanding transit, active transport, and LEV infrastructure.
While Toyota absolutely should have seen the writing on the wall years ago, it's not a problem that was limited to Toyota. The entire nation of Japan and every major tech company therein leapt headfirst into the idea of a "Hydrogen society" after the Fukushima disaster. It takes a long time to steer the ship towards the solutions everyone else is settling on when your ship is the size of a country.
Japan has no domestic oil, something they have been keenly aware of since WW2. I think they wanted Hydrogen to be the future so badly because it would remove that disadvantage.
Now Japan has to import the batteries, and the fossil fuels to charge them.
Hydrogen has significant geopolitical advantages for Japan, but it was also very unclear which path was better back then. Even in California we had political darlings like Bloom Energy and fleets of fuel cell buses crawling around city streets.
It was only around 2016 or so that battery technology and renewables started to clearly win out and it was too late then to change course.
The Toyota Mirai and the Tesla Model 3 weigh approximately the same amount and so contain approximately the same amount of imported material. Switching to Hydrogen does not reduce the amount of raw material imports compared to switching to battery electric vehicles.
What does domestic oil have to do with anything? Japan doesn't have domestic natgas either AFAIK, and you need that to make hydrogen unless you make it from electrolysis of water, which needs lots of electricity, which usually comes from fossil fuels too.
Hydrogen had no way of removing any disadvantage for them. It was just something they were ahead in and thought they could push on the world as the replacement for gasoline, and profit in the process.
Unbelievable that Toyota had the hybrid, along with Honda in goddamn 1997.
Five years later there should have been huge numbers of hybrids, and the first plug-in hybrids. Ten years later their entire lineup should have been plugin hybrid capable.
When Tesla released the Model S, they should have been heads down with a competitor. The fact that every car company could buy a Model S and drive it around and not have drop-everything skunkworks doing EV development shocks me. The fact that Toyota is among the last to do it is breathtakingly dumb.
When Tesla released the Model S, Toyota should have had, at a minimum, an effective 40 mile range PHEV with all electric mode, and by 2020, should have had options for 50/100 mile hybrids, which make PHEV hybids effectively full EVs for 95% of consumer driving.
The hydrogen shit was ridiculous. JAPAN IS AN ISLAND WITHOUT OIL RESOURCES. They import virtually all their oil. Electrification makes them much more economically independent. The only place hydrogen was coming from was oil, unless they have some unknown methane reserves I am unaware of.
Toyota is full of good engineers still, and are effectively the largest car company in terms of volume production (I know VW may technically be larger, but they seem more balkanized in brands and acquisitions).
Toyota likely could close by simply partner-acquiring one of the bigger Chinese EV makers and battery companies (although there is that wee little China-Japan historical hatred).
> The hydrogen shit was ridiculous. JAPAN IS AN ISLAND WITHOUT OIL RESOURCES. They import virtually all their oil. Electrification makes them much more economically independent. The only place hydrogen was coming from was oil, unless they have some unknown methane reserves I am unaware of.
The hydrogen was generated from nuclear power. They have a lot more of these sources than they do for a lithium ion supply chain.
> The fact that every car company could buy a Model S and drive it around and not have drop-everything skunkworks doing EV development shocks me.
I think every company did back on the envelope calculation and in about 10seconds realised they won’t ever have the battery supply to satisfy even 10% of their sales for decades. Only Tesla managed to convince Panasonic to build new factories.
> Electrification makes them much more economically independent.
The Japanese electric grid is so shitty you won't even believe it. They have single phase 100V power. Half the country is 50Hz and the other half 60Hz.
Their grid just plain can't handle electric cars at scale without a full and complete overhaul.
I don't think buying Chinese battery/BEV company is an option due to national security. Worst thing happened in Japan was Nissan sold AESC to Chinese conglomerate. Govt should relief it instead of sunsetting companies like JDI.
> It is not the first, nor the last, time that we see how a powerful CEO is replaced prematurely due to his bad relationship with the electric car.
>
> An already unstoppable trend that some are reluctant to accept, and that has cost the great executives of Ford, and Volkswagen, and now it has been the turn of Toyota.
Wasn't it just the other way round at Volkswagen? Herbert Diess steered the heavy ship Volkswagen extremely aggressive towards electrification like no other company of of this size with clearly visible results.
He was ousted due to major issues (delays, staffing, quality) with the software department (CARIAD) that is building a completely new software stack to be used for new cars of all Volkswagen brands and replaced with an e-fuel loving petrolhead, the former Porsche CEO Oliver Blume.
Yeah, I don't see how it's like post-electrification VW. Pre-electrification, yes VW had the blinders on, and acted, well, criminally. I hope VW pivoted in time to survive this transition. Minus the software issues, the ID.4 is an awesome EV - incredibly well built and premium feeling and drives absolutely great. The ID.Buzz is like a dream car for me.
As for Toyota, the sheer amount of FUD and deception they have engaged in around EVs, topped off by the preposterous claim that hybrids are superior because they are "self-charging, has left me with little sympathy for them.
However, they are still a massive force in the automotive world, and a great number of people trust them to make affordable and reliable cars, and more affordable EV options are what the world needs, not another monster electric SUV. Toyota has the manufacturing heft to deliver that, and to the extent that they do, I hope they stick around.
Yes, and it's likely that VW will shift away from their all-EV strategy. They are already investing in fuel cell trucks and e-fuels. In reality, EVs are just one step in a long chain of future changes in the transportation industry. People are too obsessed with the next step and forgetting about the steps afterwards.
EVs aren’t selling in the US. No one wants them. They are prohibitively expensive for most and have terrible resell value because once the batteries die the car itself is essentially junk.
Yup, just happened with our (ICE) 2016 Kia Sedona Minivan. The head gasket blew, had quotes from 6-10K to fix it. We sold it to an auto auction for 2K. It only had 150K miles on it and we had just paid it off.
We couldn't just swap a new engine into it, too complex, too much to fix.
"Auto makers sold 807,180 fully electric vehicles in the U.S. last year, or 5.8% of all vehicles sold, up from 3.2% a year earlier, according to year-end figures released this week by market-research firm Motor Intelligence. In comparison, total U.S. auto sales fell 8% in 2022 from a year earlier."
1/5 cars sold in California last year were EVs, 6% of all vehicle sales in the US were EVs. They'll easily sell over 1 million EVs next year and every major brand has a half dozen new models coming down the line.
There's an exponential growth curve in EV sales that is going to continue as the cars become cheaper / longer range / better made.
I live in small-town Midwest, I don't know a single person who's shopping for a new car that is shopping for an ICE vehicle. Even my friends who do a lot of towing are buying EVs because the stupid FB memes about lack of towing distance don't reflect the actual usage of pulling a boat 20 miles to the ramp and they're all tired of paying $4/gallon for a daily driver that gets 15mpg.
When the battery dies, why is it essentially junk? Can't one just swap a new battery into it? Or are you saying that because it would cost 10K+ to do that?
Replacement batteries aren't exactly like engines either. Can you replace an old big block V8 with a rotary compact engine? Not typically.
A battery just has to deliver electric current. If your electric car you bought in 1998 is NMC chemistry, and you replace that pack in 2025 with a 200 wh/kg (that is, about the same density) sodium ion chemistry battery that costs half of what the NMC would, is there some massive overhaul to the system? Maybe the battery management software needs a different set of parameters, but that's about it. Now, the cell-to-frame... well, that's a different issue.
Point is, ICE engines cost what they cost. There's no magic technology coming (not compression-combusted gasoline like Mazda has, or even the inside-out rotary will save ICE).
People don't appreciate what the forthcoming 150 wh/kg sodium ion batteries and 200-230 wh/kg LFP batteries mean for almost all urban and suburban vehicles. These batteries also don't have runaway fires, so they don't lose functional density at the pack level like NMC chemistries.
So if you had some Tesla going 400 miles with 260 wh/kg NMC, that was ACTUALLY about 180 wh/kg at pack level with cooling and safety, the 200 wh/kg LFP using modern Cell-to-Pack techniques, is that same battery. No Nickel. No Cobalt. Lithium is the limiter (and lithium supplies are largely constrained by lack of development, not scarcity like Nickel and especially Cobalt).
So if 200 wh/kg LFP can do 400+ mile cars, the math should be pretty simple on 150 wh/kg sodium ion. That's a 300+ mile car. No lithium needed even.
The roadmap for LFP is 230 wh/kg in mass production later this year. 200 wh/kg is already scaling up.
The roadmap for Sodium Ion is 200 wh/kg in a year or two, we'll see on that.
And once sulfur-based chemistries come online, which are allegedly 2-3x as dense as NMC, look out. That means battery packs that are 45% to 30% of the size of previous ones.
Also, yes batteries aren't junk when they need to be replaced. There will be a couple options:
1) the pack is likely 60-70% capacity of the original. It can be used for home powerwalls, grid storage, etc.
2) the pack can be torn apart and individual cells tested/harvested that still function, and those are reintegrated in other uses (lawnmowers? Power tools? powerwalls? Batteries are useful EVERYWHERE).
3) Recycle the whole pack to get the materials / metals back.
That's what is interesting about battery packs. They don't catastrophically die typically. Their EoL is a gradual failure, but they are still useful. Can an ICE engine near its end of life be torn up into hundreds of little engines and repackaged into toys, tools, security cameras, leaf blowers? No? An EV battery can.
So the battery being a major component cost isn't a total loss, more like a depreciating asset component. It will still have inherent value in many ways, far better than the scrap metal value of an engine from an ICE drivetrain.
Can't speak for the US but next door in Canada there are waiting lists for EVs. Second-hand EVs sell very well, too. We feel lucky we bought a second-hand, short range EV several years ago and it does almost all of our driving tasks. Haven't visited a gas station in a long time.
Do you think you just step into your EV one morning and the drive train battery is just "dead"? Are you sure you're not conflating a high tech 500kg piece of technology to the crappy bargain bin 12V battery you have in your ICE car?
The battery will degrade, that's how the laws of physics and chemistry work. But the degradation is perfectly predictable and actually (according to historical data) slower than expected. You can buy 10 year old Teslas with 80-85% battery capacity left.
So instead of 450km you can only go for 360km before needing to charge. If you're a hardcore roadtripper who does 1000km+ every weekend just for fun, you can sell it and get a new one. But the average driver doesn't do even 100km per day, they won't care.
This is exactly right. Also, gasoline cars aren't selling in the US either. No one wants them any more, because they're all buying uranium-powered cars.
This fast paced transition doesn't sit right with me, still. I feel like people are turning a blind eye to the negative environmental impacts this is going to have.
The question is does this environmental havoc replace or lesson the current environmental havoc + military and political conflict over oil supplies (yes potential for rare earth or other material conflicts persist).
As always though, this move is optimizing the wrong thing - we don’t need more efficient cars we need fewer cars. But nobody likes subtractive solutions.
It's not a matter of subtractive solutions or not: It's that in a low-car environment, way too many people's real estate investments are worth near zero. How much of, say, Suburban Florida remains usable if we price cars high enough to make their use unadvisable? Entire subdivisions are worth basically zero. Same thing with commercial areas that are not really reachable on foot.
Old US cities only became car centric through massive amounts of pain and hardship, which happened to hit people that were mostly politically disenfranchised. Reshaping in the other direction would involve a similar amount of hardship, but on people that vote. We can make it easier to increase density, but the kind of efforts that would make us not end up relying on EVs have such economic and political costs that we lack the state capacity to go there.
> How much of, say, Suburban Florida remains usable if we price cars high enough to make their use unadvisable?
Idk. How much remains usable if it’s under water? Should we let people in Florida tax the rest of the country for their road development? Can Florida afford to maintain and build the roads they want to build?
> Old US cities only became car centric through massive amounts of pain and hardship, which happened to hit people that were mostly politically disenfranchised.
Can you elaborate on this? How are you accounting for highway development that destroyed minority neighborhoods in this assessment?
Well, many (not all) want car-only infrastructure, but they've also been unable to realize the true cost of their decisions, hence South Florida will be underwater. It costs too much money to build and maintain the infrastructure that would be required to maintain the lifestyle. So far things haven't gotten too bad but insurance companies are beginning to refuse to insure homes in Florida and so it has been left to the state to subsidize at a loss. Similarly as the state continues to build out unmaintainable car-only infrastructure and attempt to keep much of the state from "going underwater" it'll require either transfers of wealth from other states or increases in taxes. Neither of those proposals are politically viable either, so eventually the infrastructure just won't be maintained.
The timeline is interesting but I think it's slow enough for regulation to catch up.
This shifts the focus of problems from many different places to one. In the article you linked, it mentions alternatives to reduce lithium needs including smaller batteries, and battery recycling.
This is much easier to regulate, and there is plenty of time to do so - although yes this is putting some trust on governments doing the right thing.
Mining for combustion cars also breaks havoc and nobody cares.
It would be best to reduce our car dependence, but I guess a new electric car is still better than a new combustion car.
It's so funny to me that a few pounds of lithium brings out so much hand wringing, whereas all that copper and even ton(s) of steel does not. Or for that matter, the far more massive amounts of hydrocarbon extraction!
If somebody is even half serious about these concerns, they had better be advocating for extreme reduction in car use. Otherwise it's pure hypocrisy.
At some point, the illusion that we will be able to avoid changing our transportation infrastructure in the US, will be unmaintainable.
The problem is not in EVs, it's in private automobiles, our settlement patterns, and our utter lack of funding public transportation in all of its forms.
At some point we need to stop acting like transportation solutions for areas with orders of magnitude higher population density than the US are obvious solutions. Infrastructure for a country like the Netherlands (a popular “see we should bike” example) with a population density of 459 people per km^2 is going to be completely different than the US with its 35/km^2.
It is just as naive to think the US can remake its transportation infrastructure to be like Europe, as it would be to expect every road in Italy to be made wide enough for a Ford F-150 Raptor. Places in the US with high population densities (NYC, DC, Chicago, SF, etc) often do have far better public transportation than the rest of the US.
> with a population density of 459 people per km^2 is going to be completely different than the US with its 35/km^2.
This is a silly comparison though. Large swaths of the US are either completely uninhabited or nearly completely uninhabited.
If you want a better comparison, look at New Jersey. Its population density is 488 people per km^2, so a little higher than the Netherlands even, yet its infrastructure is dismal comparatively despite having the density to support Netherlands-style infrastructure. Almost all major population centers in the US look like this -- dense enough to support much better, but yet we don't have it. The fact that it wouldn't work in the vast rural expanses of e.g. Wyoming don't mean that it wouldn't work for our big metropolitan areas.
Kinda so-so article that gets some issues exactly right (oversized vehicles, too many individual cars vs transit options) and badly misses others, like lithium sources.
Lithium deposits are geologically widespread and abundant, but 95% of global production is currently concentrated in Australia, Chile, China and Argentina. Large new deposits have been found in diverse countries including Mexico, the US, Portugal, Germany, Kazakhstan, Congo and Mali.
There are massive Lithium deposits at the salton Sea in souther California which are just bubbling up out of the ground in heated brine, meaning the earth is doing most of the work bringing it to the surface as mud. Refining it will need significant water, either from contested supplies fed by the Colorado river or as-yet-unbuilt water pipelines from desalination plants at the coast. But these deposits are massive and the extraction part of the process would have minimal environmental impact compared to the open-pit mining required elsewhere. It's odd that this article doesn't mention this at all.
In the 50k miles I’ve had my EV, I’ve saved at least 48 barrels (~2400 gallons) of gas from being burned vs the gas car it replaced. The (very slow) rate of battery degradation suggests at least 150k+ miles on this battery pack.
I have a hard time envisioning that the impact due to lithium mining for one battery pack is worse than the extraction and pollution from burning ~150 barrels of gas. Plus another 3 barrels of motor oil from oil changes.
Not to mention, they are forecasting out over 25 years, on a technology that has been rapidly changing, and is seeing immense investment. Batteries from 15+ years from now will have very different chemistries, and lithium will likely have safer sources. The Chevy EV1 launched with lead-acid batteries about 25 years ago - modern EVs aren’t remotely similar.
The site is obviously quite biased and there doesn’t appear to be a shred of evidence in it that this has anything to do with EV. It looks like a site heavily biased towards EV is just making baseless claims.
"However, reports from Nikkei[1] and Reuters[2] attribute the decision to the automaker's slow response to a rapidly changing automotive industry, specifically the adoption of electric vehicles. "
> This morning it has been confirmed that Akio Toyoda, grandson of the founder of Toyota and in command since 2009, will leave his position as head of the Japanese brand.
This entire article is based on unsubstantiated conjecture and probably wrong.
Koji Sato (his replacement) is currently head of Toyota's racing and luxury car divisions. Nothing about this move indicates it is specifically about EVs.
I get that Toyota is still really late with an EV option, but their PHEV selection is still probably best in the industry and they can't make enough of them to keep up with demand.
Yep - I'm generally a fan of the Toyota brand and hope for their continued success - but they definitely need to make more cars like the RAV4 Prime. If the dealer markups and lack of inventory on the RAV4 Prime continue it will definitely be a missed opportunity.
Same. They made their entire Sienna lineup go hybrid by default and the vans have been unobtanium ever since.
I think the idea that they should start taking away resources from cars that are already beloved and selling well to (potentially) throw away their reputation on trust and reliability seems incredibly short sighted.
And given that they are the number one seller of cars in the world, incremental improvements in fuel efficiency fleet wide seem like a much better use of their time than providing a gimmicky electric model just for California.
The b4zx was so bad that nobody can figure out how they managed to miss the mark so badly.
It's more expensive than others in the same category, it has worse range, no battery heating - or preheating, only two fast charges per day. And even the "fast" charging is at under 5kW levels if it's even close to 0 C outside.
Why would I pay over 10k more for that instead of a Model Y or Ioniq 5?
6. Ahh yes, BMW press release about BMW testing a BMW car themselves. Totally neutral and unbiased. Toyota had the same thing, they preheated the car before each run because fuel cells really don't like freezing.
Hydrogen works nearly exactly like CNG. People have created fantasy stories as if it was the blood from Xenomorphs. In reality, it's corrosiveness is pretty underwhelming. Actual issues related to corrosion or hydrogen embrittlement only happens after decades of exposure or in specific situations. As long as you avoid these specific scenarios and do proper maintenance, you do not have a problem.
It can be extrapolated that fuel cell cars will similar in most aspects to CNG and LPG powered cars which also have to deal with pressurized gases.
A lot of the anti-hydrogen articles are paid marketing from competing technologies. They are basically not stories at all. FUD is more accurate.
> Ahh yes, BMW press release about BMW testing a BMW car themselves. Totally neutral and unbiased. Toyota had the same thing, they preheated the car before each run because fuel cells really don't like freezing.
Considering that they are actually selling these cars, they are not going to lie about real world performance. Independent testing have found fuel cells to work better than batteries in cold weather: https://www.sustainable-bus.com/news/the-effect-of-cold-weat...
Fuel cells do work better if "work better" == less range lost due to cold weather. Hydrogen doesn't care about weather at all, Batteries do.
But what I'm worried here is what happens if I park my Hydrogen powered BMW next to my ski holiday cabin in -30C weather for a week, will it still work after that? Does it keep the fuel cell above freezing at all times somehow? Or can it dump the produced water out of the cell so it freezing and expanding doesn't break anything?
Gasoline engines will start if the engine is in good order and the 12V battery has enough juice to crank the engine to get a proper spark.
Diesels will have some issues because the oil is too thick when frozen, but if the 12V battery is in good shape you'll usually make it. You do need to run it for a good while to warm everything up before actually moving.
A hybrid (non-PHEV) Prius will start like it's a summer's day. It uses the drive battery + engine as a starter motor, so it'll just go. The oil in Priuses is so thin it doesn't really change viscosity due to weather that much.
EVs have zero issues. Step in, push button and it'll take about 4-5 minutes for it to be nice and warm inside without any preheating.
Sauce: have started all in -30 to -35 weather every winter.
I'm actually excited for the biggest motoring magazine over here to do their winter test on a Hydrogen car. They don't pull punches for anyone - Teslas for example have huge issues with heating during extreme colds, some valve in the engine freezes over and the heat never gets in the cabin.
Definitely should, but I've seen zero independent reviews stating so - which is a bit suspicious.
There are a TON of winter tests for journalists, all organised by the car maker. There are also a bunch of buff articles and videos about hydrogen cars in cold weather conditions.
Also manufacturers aren't pushing H2 cars too hard in Canada or Nordics/Scandinavia either. It's all just Californian sun or the parts of Europe where -5C is especially cold.
I have mixed feelings on ecars but ultimately see them as a necessary evil
And Toyota's recent announcements that they were seemingly going to put off ecar dev until we were all underwater was pretty incredible even knowing their hate for electric
So this move is prob going to save millions of lives
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[ 2.6 ms ] story [ 220 ms ] threadToyota is one of the most trusted brands across the world. Their cars have extremely high resale value and are generally known to have long usable lifespans. Hydrogen issue aside, they are (at least currently) not 'far behind' their competitors.
https://www.toyota.com/mirai/2023/features/
The fuel cell can't produce electricity fast enough to power the engines for proper acceleration and the battery doesn't have enough buffer.
FCEVs are chemical in the same sense that BEVs are, because a “fuel cell” is, like a battery cell, an electrochemical cell.
The only real difference is that the “fuel” and “waste” are inside a battery, but come from and go to the outside in a fuel cell, which means that an FCEV can be fueled (and exhausts) like an combustion engine vehcile, despite being fully electric.
So are batteries too
They're already a decade behind where they could've been. The main problem is not that it won't take them long to start, but that it's been so damn long already and they've wasted all that time and haven't even started in earnest yet. Market share takes time to earn and they've given competitors a huge lead for no real reason at all beyond their absurd fixation on hydrogen.
The one thing that EVs require is an EV charger network to exist in the foreign countries that Toyota sells the cars to. Without an existing EV charger network, it becomes a chicken and the egg problem for Toyota since, as a Japanese company, it would likely face a difficult time getting financing to build EV charger networks in foreign countries.
Hydrogen fuel theoretically would just be an adaption of the existing petrol gas station infrastructure so the existing players/gas station networks would just need to switch over.
Now that ElectrifyAmerica is more "a thing", Toyota can start shifting strategies.
VW and Tesla/US car brands could move faster since they were required (VW) or had home court advantage and government support (Tesla/US car brands) to finance the US EV networks. The Korean autos switched earlier as they were probably more hungry and had less to lose on ICE than the Japanese incumbents.
There's also the game theoretical play that being the only major petrol based auto producer could lead to pricing power if the transition takes longer than expected.
I charge my EV at home. I’ve charged my EV on someone elses charge (because i needed it, not because I got a better parking space) maybe twice since i moved to an EV with a 180 mile range. Heck, even with my “first gen” EV with a 63 mile range, I charged at home 95ish percent of the time, and those days are behind us now.
$2k to run a 240v external outlet, $500 for a charge station, and you’re set. Apartment dwellers still have issues, but thats simply because govmt/demand hasnt insisted yet.
This could be solved today by using Tesla's Supercharging network, or at least their NACS[0] connector in the North American market. I know that auto makers don't want to rely on each other for _reasons_ but siding with Tesla would give them an instant charging network and completely solve the problem in one go.
[0] https://www.tesla.com/blog/opening-north-american-charging-s...
Think Titanic
I think most car companies underestimated how easy it would be to 'go electric'
Let's see how many power players inside Toyota try to drag down the company to try to salvage some dignity of the hydrogen guy
Sure and all coal plants will be replaced by fusion, but a utility executive single-mindedly pursuing fusion is not a good corporate leader.
And if you replace "fusion" with "fission" it is a very sensible argument.
Maybe globally because India/China, but the US has shed Gigawatts of coal capacity over the last two decades.
> It's most likely replacement is... natural gas.
Yeah.
> And if you replace "fusion" with "fission" it is a very sensible argument.
Like it or not, we are losing our ability to build fission plants (Google Vogtle if you’re not familiar) and the only way an Electricity CEO in 2023 should be single-mindedly thinking about fission is if they have some inside information that the government is going to subsidized the heck out of it.
Otherwise, they'll just be the CEO with unconstrained capex and higher prices (and an angry utilities commission that has a singular mission to cut the rate base to reduce said prices as much as possible)
Coal is nowhere near dead. Europe is increasing production right now. People have greatly exaggerated the death of fossil fuels. We are decades away from moving away from fossil fuels.
A lot of the opposition to nuclear fission is just bad environmentalism. Take that away and we'd be building hundreds of reactors right now. We can easily reduce construction cost if it wasn't for excessive regulation designed to make it expensive.
Yeah.
>Coal is nowhere near dead. Europe is increasing production right now. People have greatly exaggerated the death of fossil fuels. We are decades away from moving away from fossil fuels.
Again, Yeah.
>A lot of the opposition to nuclear fission is just bad environmentalism.
This is categorically wrong. A lot of the opposition to fission is that it is not cost competitive with natural gas. Again, please google Vogtle. It took $30bn and 15 years to add two gigawatts of generation capacity to our grid.
Meanwhile, Indeck Niles in Michigan took $1bn and 2 years to add one gigawatt.
>We can easily reduce construction cost if it wasn't for excessive regulation designed to make it expensive.
I'm going to need a citation on all of this. What regulation exactly caused Vogtle to cost $30bn? Was it the regulations that the site should be built to spec and not leak[0]?
>In August, the U.S. Nuclear Regulatory Commission found two sets of electrical cables meant to provide redundancy in Unit 3 weren’t properly separated. Earlier, Georgia Power had to repair a leak in Unit 3′s spent fuel pool
[0]https://www.augustachronicle.com/story/news/2021/11/04/georg...
The type of problems that are reported at nuclear power plants are basically ignored at other plants. Most power plants don't have any real redundancy, nevermind the insane levels of redundancy requires at nuclear power plants. The plant would have easily ran with those issues, but we just refuse to take even the smallest risk.
Yes. Forced outages are typically complete rather than partial. They're heavily correlated and last months. So storage or backup needs to be many weeks to make it reliable at even the 95% level. Much of the generation happens at night when industries have to assign expensive graveyard shifts to utilize it effectively. It's also so expensive that increasing coverage for a set power target by overprovision is prohibitive.
> It is also the result of decades of low investment into nuclear until expertise has retired and now we struggle to find the right people to build new reactors
This must have been why reactors completed in 1979 were on average so much more expensive than the ones finished before. And why prices have gone up almost every time the same design is built again.
> The plant would have easily ran with those issues, but we just refuse to take even the smallest risk.
I love this line where you crow about how safe it is out of one side of your mouth, then whine about how if it didn't have to be safe, it'd be cheap. Let's replace the 'excessive' regulatory requirements with removing the liability cap and see who lines up to provide insurance on an entire city.
Also the residents around kadapa or husab would love it if they could have some of this safety you're talking about.
Again, we are constantly adding more and more requirements to nuclear reactors. Everything must have quadruple redundancy these days.
You forget that nuclear is the safest or form of energy that we have. The number of deaths from nuclear energy is remarkably small. Sure, we can still insist on insane levels of safety, but we should not then turn around and demonize the end result. If we insist on these regulations, then we should also insist that people be aware of what is driving these costs, and make it a positive thing.
When they were new and before the regulations they were on less than half the time. Another lie
> You forget that nuclear is the safest or form of energy that we have. The number of deaths from nuclear energy is remarkably small. Sure, we can still insist on insane levels of safety, but we should not then turn around and demonize the end result. If we insist on these regulations, then we should also insist that people be aware of what is driving these costs, and make it a positive thing.
There it is. Right on cue, after already being calledout for it.
You're demanding free insurance. The insurer gets to set the policy on likelihood to destroy a city. Stop crying or findyour own insurance.
Also this is a myth. Solar is now the safest by a factor of two. Then wind. You continue to lie about everything.
If you include all the deaths from mining waste dumping and lung cancer of uranium miners, eye witness reports of chernobyl liquidators rather than official ussr reports, and the hundreds of unremediated sites that are less than 1% of their final age, then hydro beats it too.
Going from gas to electric is slow.
If electric -> hydrogen offers fewer of the benefits beyond removing a dependency on battery metals over much-cleaner-already EVs, that transition will take even longer, if it happens.
Short list and no nowhere near exhaustive list:
Extremely high pressures required to get sufficient energy density
Hydrogen embrittlement basically requiring expiration dates on tanks in vehicles
Inefficiency/cost of green methods for producing hydrogen
How to create cheap fueling stations like we have with gas stations
That isn't to say these problems are not solvable but we have been working on them a long time and haven't made a ton of progress. Meanwhile EVs have already been able to overcome most of the big hurdles. I think hydrogen has a possible future in aircraft because the issue of cost, maintenance, and special equipment for fueling is status quo for aircraft already.
Hydrogen has a ton of shortcomings still. Technology might improve some of those too, sure. But if 75%, say, of the most severe environmental impacts of cars are mitigated by EVs, leaving a much smaller-sized problem in their wake, the technological advancements will have to be proportionally even stronger and easier to overcome to make the market move on again. (Or if EVs never replace >80% of new gas vehicles or so... but if inertia against change is that strong, that's not a benefit for hydrogen advocates.)
The biggest advantage of hydrogen is that they also solve the most severe environmental consequences of conventional cars, just without creating new ones of their own. It is similar to how LED lightbulbs replaced CFLs, even though CFLs were seen as necessary to replace incandescent bulbs.
80's electric RC cars were slow and the battery ran out in 5 minutes. People who wanted power used ICE RC cars.
Then we got li-ion and LiFePo4 batteries and brushless engines. Now the cars are so fast that regular people need to use limiters when driving. You can get a electric RC car up to 80km/h with off the shelf parts easily.
> battery related metals
only one of these continuously emits greenhouse gasses through its use
hint: it's not the one that you can recycle into new batteries
What makes you believe the current gas network can be used for Hydrogen? I don't believe this is the case, but would be interested in seeing evidence to the contrary.
The grid can handle overnight charging just fine, there's more than enough transmission and distribution capacity.
Natural gas pipelines can not be used with hydrogen without some as of yet undiscovered coating. Plus these pipelines are single use; are you going to stop all gas usage in all houses before we let people fill up at stations or homes?
We can use exactly zero of the current gas distribution system for hydrogen. Hydrogen molecules are literally the smallest in the universe, we haven't invented a container where they won't escape. You can't just pour hydrogen into a gas station tank or transport it in a natural gas pipe.
Transporting hydrogen will always result in huge losses. Less huge if you transport it as a liquid, but then you need to transport it at -252 Celsius - which brings a whole new set of problems.
My chevy bolt will charge at 8a (conservative) or 12a (“fast”) at my preference. It takes maybe 3-4 hours over night to charge from my average driving day with a decent commute.
My car consumes, while charging for a few hours overnight, about the same amps as a good clothing iron or a beefy vacuum. If i wanted, i could delay charge so three EV charged overnight, never draeing power at the same time.
My next car will buffer power so solar cells can overcharge and supply back to the house. And it will be a backup power supply for storms and grid outages so I no longer need a standby generator.
Tell me again about how the grid isnt ready for my BEVs and why we should be pumping some liquid or gas into tanks?
It is the same reason why we have miles of natural gas pipelines sending NG to local NG turbines instead of a few big NG power plants with wires sending electricity everywhere.
Hydrogen we need to make using a resource intensive process, and it leaks from every single container ever made, because it's literally the smallest molecule in the universe. Hydrogen transport incurs so big losses that it's not feasible at a large scale [0].
To move an equal amount of energy, you need 4x many ships as LNG, because you lose 23% more during transport than LNG AND you need to transport it at -253C which is a whole another issue.
Hydrogen is a good energy storage medium, but it's not practical for transportation. It's a lot easier and cheaper to move the same amount of energy using the power grid.
The future of hydrogen is renewable energy storage, on location. Not transport.
[0] https://vimeo.com/761934482 (16:50 mark)
You do not need 4x as many ships. You just need bigger tanks. Hydrogen is much lighter than LNG. Bigger tanks are not an issue. You're hearing straw-engineer arguments from those with a vested interest to BS about these issues.
Why would the World Hydrogen Congress have a "vested interest to BS"?
The speaker is comparing a LNG ship to a prototype Kawasaki LH2 ship, with actual values for both.
What he's suggesting is that we transport ammonia instead of LH2, ammonia is a lot more stable to transport and can be converted to hydrogen at the destination.
Ammonia is an option too. But this does not preclude other ideas.
We have an electrical power grid, dude. And it works just fine for home BEV charging.
A dependency on fossil fuels isn't a good thing, certainly not to the extent that we've developed, but I really don't think the answer is as clear cut as everybody treats it to be.
The grid will require significant investment no matter what at this point. Many parts are nearing the end of their useful lifespan, being built more than 50 years ago. Renewables and electrified transport definitely add to it, but people are trying to pin the entire cost on those things which is just wrong.
Not really. Batteries are energy storage, oil is energy production. Most of the energy used to charge batteries comes from burning fossil fuels.
Even if we convert the grid to 100% renewables and get rid of fossil fuels, we will still need to mine for battery materials.
But we'll no longer need to extract and burn fossil fuels, which is where the vast majority of the environmental benefit comes from. You can't say "Aside from the main overwhelming benefit, it doesn't look so good"!
You're conflating different things. Battery production does not mean we will automatically get 100% clean energy. Gasoline in cars accounts for like 15% of the US's fossil fuel usage.
Again, batteries are energy storage. Not energy production.
This idea that batteries --> clean energy --> All negatives of batteries must be ignored is disingenuous and wrong.
It's not productive.
Bottom line batteries/electricity generation do less ecological damage today than gas/gas tanks, and every year the gap will increase.
The fact you can charge you EV at home (from your own solar panels if you have then) is a massive added bonus that's going to be hard to convince people away from once its established.
Thinking about what comes after battery cars (assuming there's a Lithium shortage) - I'd be very surprised if Hydrogen can scale up; I think it's much more likely we move to other battery tech, or perhaps novel liquid fuels. Hydrogen was always a greenwashing ruse by petrolchem companies.
They don't actually want a hydrogen vehicle, they just don't want an EV and use "hydrogen is coming Soon(tm)" as justification for it.
Like the one report that warned us that the earth didn't have enough lithium to electrify everything.
Turns out they calculated that we need, for some reason, enough batteries to store a full month's worth of global electricity production in batteries. No wonder they got the fancy headline :D
Battery tech is constantly evolving. There are cobalt-free and lithium-free batteries in the pipeline already. We even have wood-based batteries on experimental stage: https://www.bbc.com/future/article/20221215-the-batteries-ma...
But it's not worth it, since you are just carrying a big tank of water for no reason. It is a smarter solution that a battery which does carry everything at all times.
Most of what you say is not that different than what people said about batteries. Let's not forget that li-ion batteries are really hard to make and have their own major challenges, and for a long while seemed like a terrible idea. The story is basically repeating with anti-hydrogen arguments.
This includes the dumbest of them all: that it is just a conspiracy by oil companies. Last I checked, there is no carbon in hydrogen, and "novel liquid fuels" will imply adding carbon to it. So either it is not a conspiracy by the oil companies, or the oil companies were right all along.
Hydrogen is not burned in a fuel cell. It works the same way as lithium does in an li-ion battery. However, you can use hydrogen in a combustion engine, also as a compound for energy storage. Also, "fuel storage and refueling" is a huge advantage because you don't need to worry about slow recharging. This is often seen as an advantage.
You might rather refer to a color-coded periodic table which shows which elements are gases and which are solids at room temperature. That's a much more relevant concern than whatever you're trying to say.
You mean like sodium ion batteries that are coming into mass production this year at 150 wh/kg? (aka the 200-300 mile car) That don't even require lithium?
You mean like Lithium Sulfur batteries that are poised in five years to double or triple battery density?
Or you mean like the Sodium Sulfur batteries that will probably come a year or two after that which similarly double/triple NMC capacity but only require sodium and sulfur?
Your take is ten years old. High density LFP and good-enough density sodium ion is going to deliver a comprehensively cheaper car drivetrain than ICEs can deliver, and each year will only be worse and worse news for ICEs. I would predict by 2030 there will be 600 mile range EVs (real world, not WLTP) whose drivetrain component cost is 1/2 of an ICE.
We'll have to see what comes out of Toyota. They have the DNA of execution, efficiency, and engineering. It's hard to see if it is "too late", because EV transition is such a massive investment in vertically integrated manufacturing at this point, while carmakers outside of Tesla are so OEM focused. We'll see.
I had kind of assumed that Toyota would be asleep at the switch and a joke for another 2-3 years, this is a surprising development. The fact they were pushing hydrogen still last year in public and poo-pooing EVs, and given the ossification and malaise of large Japanese corporations, I assumed it would be status quo until substantial market share was lost.
Is this activist investors again, like BMW, VW, etc? Is that even a thing in Japanese megacorps?
All the hydrogen generation/splitting facilities (it all comes from methane, right oil company astroturfer?)
I forget, did you guys fix the various fundamental laws of thermodynamics so that you can get hydrogen from water at high efficiency? You know, water, that ultra-stable molecule? Or should we just ship the electricity over the existing grid rather than take 30-50% losses putting it into hydrogen, physically ship it with some new fangled hydrogen tank truck, and then get the energy out?
So how much energy do you use to GET to that 1000 wh/kg? Oh right, you'll really just get it from methane or tar sands or fracking or whatever. Right oil company executive.
All the hydrogen transport infrastructure. Does hydrogen like being in tanks? I forget. Does it basically leak from everything? Hydrogen is really stable, right?
All the hydrogen refuelling stations. Wait, is hydrogen a liquid? Oh, it's a gas? man, those'll be annoying to engineer. Right, bet that's a solved problem for Joe Q public.
All the fuel cells that last longer than 100,000 miles. I forget, did you fix that little platinum problem? Right, solved problem.
Here's the real kicker: what price are you targeting with hydrogen cars and infrastructure? It'll take, what, 10 years to get close to what the electrical grid and current recharging stations offer? I mean, we have EVs like NOW. Lots of them. Hyuuuuge factories. Does the "hydrogen economy" exist yet? Right, only if you use methane? Gotcha oil company dude.
I forget, can I slap some solar panels on my roof (especially those perovskite multijuntion ones that I hope come out in a few years) and directly use that to generate hydrogen for my hydrogen car? Oh, is that a bad idea? I should just use an EV?
Don't get me wrong, hydrogen has potential to be useful. Medium/long range aviation, really long haul shipping, really long haul trucking. You know, edge cases. You know, unless synth fuels become a thing.
So just to reiterate:
1) you have no factories for a mass production car
2) you have no green production of hydrogen
3) you have no transportation infrastructure
4) you have no pumps/refueling
5) it'll take, what 10-20 years to get to where EVs are right now?
While EVs:
1) have factories / in production
2) can use any generation source, just hook it to the grid.
3) transportation? You mean the grid? Or generation at home?
4) recharging stations, while yeah, not what gas stations are, they exist and are actively being built out
5) and just to reiterate, there's been production EVs for... 15 years now?
Your little hydrogen bus system in Japan? I almost guarantee that gets chucked once cheap EV buses hit the mainstream (they don't need to go far, they do lots of stop-go so regen, it would be really nice to charge them off the grid, they will be cheap/in mass production). I mean, if you're a city, would you like supported / non-bespoke cheaper-than-ICE buses with low maintenance cost, cheap repair, or some screwy hydrogen thing?
Yeah.
Fuel cell age is measured in hours, not miles. Every second your car is powered, the fuel cell is expiring.
We are also not discussing the viability of EVs and hydrogen cars right now, but what will happen in the future. After all, the start of this conversation is about Toyota somehow missing the boat on EVs. But people are forgetting that EVs are not the final step in the evolution of cars.
In reality, people are just repeating similar claims against hydrogen vehicles as people in the past have against EVs. The problem is that EVs have their own fundamental weaknesses that will probably never be solved. Those weaknesses will eventually require an alternative, of which the most likely is hydrogen. In that case then, Toyota is not missing out on anything.
The Toyota Mirai, which is the crown jewel hydrogen vehicle at the moment, has only 5000 hour life span on its fuel cell. You'd think they'd install one of those tens of thousands of hours one in it if they could?
You are aware that nearly all commercial hydrogen comes from fossil fuel extraction, yes?
It's obviously just history repeating itself. People complain about current emissions while ignoring future emissions. In hydrogen's case, it is the same as electricity. It is as green as the source energy, which in the long run will be green.
VRE has produced more world wide than Nuclear for several years now, and is increasing at roughly 1/4th of the cumulative size of the entire nuclear fleet every year.
And that is with a dramatic reduction in nuclear power in recent years.
Edit: LOL even your own source has the correct answer further down the page (which is still 2 years of massive expansion under current production) https://ourworldindata.org/grapher/electricity-prod-source-s...
Here's you're 'recent' 'dramatic reduction'
https://pris.iaea.org/PRIS/WorldStatistics/WorldTrendinElect...
2021 Nuclear production was the historic max.
Why does the industry and pro nuclear crowd lie constantly about even the most trivial and inconsequential things?
Also, Eastern nuclear power growth has displace Western nuclear shutdowns. So the total amount is in fact a plateau. I did not know that until now.
Ultimately, the main issue is still the problem of intermittency. Until it is solved, VRE is actually much less useful than it seems on a chart. Even in a scenario where it exceeds 100% of demand, there will still be huge shortages on certain days. Ironically, the best way of solving this is via hydrogen production, but VRE advocates despise that idea.
Last I checked it was almost a month into 2023, not part way through 2021 when the production had been higher for a whole year already.
> Also, Eastern nuclear power growth has displace Western nuclear shutdowns. So the total amount is in fact a plateau. I did not know that until now.
So you made up whatever you decided sounded good about today's producton?
> Ultimately, the main issue is still the problem of intermittency. Until it is solved, VRE is actually much less useful than it seems on a chart. Even in a scenario where it exceeds 100% of demand, there will still be huge shortages on certain days. Ironically, the best way of solving this is via hydrogen production, but VRE advocates despise that idea.
So you made up the stuff about the scope of production, doubled down on it when called out, and now you're making up stuff about intermittency. And finally you're trying to conflate rejection of hydrogen where it is appropriate with calling out your blatant fossil gas propaganda and shilling for hydrogen cars.
I am not a walking encyclopedia. But you are a troll for acting like this.
The point was that VRE is still a tiny part of the overall grid. It will stay like that for a long time to come. And the original point that hydrogen is some kind is scam for not being green enough right now is pure hypocrisy, because the grid is in a similar situation.
And you immediately ignored the relevant points before launching into ad hominem and spouting off a conspiracy theory. Ironically, proving my point about how VRE fans do not want hydrogen production even though it solves the biggest weakness of VRE. Proving that VRE fans are just trolls these days and have nothing of relevance to say.
> The point was that VRE is still a tiny part of the overall grid. It will stay like that for a long time to come.
13% and growing exponentially by 5% of the total yoy isn't tiny. And intermittency doesn't even impose a need for dispatch, interchange, or storage until it hits at least 75%.
> And the original point that hydrogen is some kind is scam for not being green enough right now is pure hypocrisy, because the grid is in a similar situation.
Burning hydrogen for transport or heating is a much worse plan than using electricity directly. On top of heat pumps existing, seasonal sensible heat storage has a higher volumetric energy density than hydrogen, electric elements are much more efficient than electrolysis + transport, and fuel cells + electrolizers are worse than batteries by pretty much every metric.
> And you immediately ignored the relevant points before launching into ad hominem and spouting off a conspiracy theory. Ironically, proving my point about how VRE fans do not want hydrogen production even though it solves the biggest weakness of VRE. Proving that VRE fans are just trolls these days and have nothing of relevance to say.
Again, you're trying to conflate rejection of shoe-horning grey hydrogen into nonsensicle places whilst pretending it's green with rejection of hydrogen.
This conversation is going to end here. You are simply not worth debating against. You're just a huge troll and are wasting everyone's time by acting like this.
Similarly stating an outright falsehood with the source in front of you isn't a mistake, it's a lie. One that is part of the current fossil fuel and nuclear misinformation campaign.
You having a tantrum and cry bullying when your lies are pointed out doesn't make me a troll. Quite the opposite.
Now Japan has to import the batteries, and the fossil fuels to charge them.
It was only around 2016 or so that battery technology and renewables started to clearly win out and it was too late then to change course.
Hydrogen had no way of removing any disadvantage for them. It was just something they were ahead in and thought they could push on the world as the replacement for gasoline, and profit in the process.
Five years later there should have been huge numbers of hybrids, and the first plug-in hybrids. Ten years later their entire lineup should have been plugin hybrid capable.
When Tesla released the Model S, they should have been heads down with a competitor. The fact that every car company could buy a Model S and drive it around and not have drop-everything skunkworks doing EV development shocks me. The fact that Toyota is among the last to do it is breathtakingly dumb.
When Tesla released the Model S, Toyota should have had, at a minimum, an effective 40 mile range PHEV with all electric mode, and by 2020, should have had options for 50/100 mile hybrids, which make PHEV hybids effectively full EVs for 95% of consumer driving.
The hydrogen shit was ridiculous. JAPAN IS AN ISLAND WITHOUT OIL RESOURCES. They import virtually all their oil. Electrification makes them much more economically independent. The only place hydrogen was coming from was oil, unless they have some unknown methane reserves I am unaware of.
Toyota is full of good engineers still, and are effectively the largest car company in terms of volume production (I know VW may technically be larger, but they seem more balkanized in brands and acquisitions).
Toyota likely could close by simply partner-acquiring one of the bigger Chinese EV makers and battery companies (although there is that wee little China-Japan historical hatred).
The hydrogen was generated from nuclear power. They have a lot more of these sources than they do for a lithium ion supply chain.
I think every company did back on the envelope calculation and in about 10seconds realised they won’t ever have the battery supply to satisfy even 10% of their sales for decades. Only Tesla managed to convince Panasonic to build new factories.
The Japanese electric grid is so shitty you won't even believe it. They have single phase 100V power. Half the country is 50Hz and the other half 60Hz.
Their grid just plain can't handle electric cars at scale without a full and complete overhaul.
Wasn't it just the other way round at Volkswagen? Herbert Diess steered the heavy ship Volkswagen extremely aggressive towards electrification like no other company of of this size with clearly visible results.
He was ousted due to major issues (delays, staffing, quality) with the software department (CARIAD) that is building a completely new software stack to be used for new cars of all Volkswagen brands and replaced with an e-fuel loving petrolhead, the former Porsche CEO Oliver Blume.
As for Toyota, the sheer amount of FUD and deception they have engaged in around EVs, topped off by the preposterous claim that hybrids are superior because they are "self-charging, has left me with little sympathy for them.
However, they are still a massive force in the automotive world, and a great number of people trust them to make affordable and reliable cars, and more affordable EV options are what the world needs, not another monster electric SUV. Toyota has the manufacturing heft to deliver that, and to the extent that they do, I hope they stick around.
Not sure how Oliver Blume was an improvement. They are just going with what they know vs. what they need.
We couldn't just swap a new engine into it, too complex, too much to fix.
1/5 cars sold in California last year were EVs, 6% of all vehicle sales in the US were EVs. They'll easily sell over 1 million EVs next year and every major brand has a half dozen new models coming down the line.
https://www.veloz.org/wp-content/uploads/2022/10/Q3-2022_EV-...
There's an exponential growth curve in EV sales that is going to continue as the cars become cheaper / longer range / better made.
I live in small-town Midwest, I don't know a single person who's shopping for a new car that is shopping for an ICE vehicle. Even my friends who do a lot of towing are buying EVs because the stupid FB memes about lack of towing distance don't reflect the actual usage of pulling a boat 20 miles to the ramp and they're all tired of paying $4/gallon for a daily driver that gets 15mpg.
A battery just has to deliver electric current. If your electric car you bought in 1998 is NMC chemistry, and you replace that pack in 2025 with a 200 wh/kg (that is, about the same density) sodium ion chemistry battery that costs half of what the NMC would, is there some massive overhaul to the system? Maybe the battery management software needs a different set of parameters, but that's about it. Now, the cell-to-frame... well, that's a different issue.
Point is, ICE engines cost what they cost. There's no magic technology coming (not compression-combusted gasoline like Mazda has, or even the inside-out rotary will save ICE).
People don't appreciate what the forthcoming 150 wh/kg sodium ion batteries and 200-230 wh/kg LFP batteries mean for almost all urban and suburban vehicles. These batteries also don't have runaway fires, so they don't lose functional density at the pack level like NMC chemistries.
So if you had some Tesla going 400 miles with 260 wh/kg NMC, that was ACTUALLY about 180 wh/kg at pack level with cooling and safety, the 200 wh/kg LFP using modern Cell-to-Pack techniques, is that same battery. No Nickel. No Cobalt. Lithium is the limiter (and lithium supplies are largely constrained by lack of development, not scarcity like Nickel and especially Cobalt).
So if 200 wh/kg LFP can do 400+ mile cars, the math should be pretty simple on 150 wh/kg sodium ion. That's a 300+ mile car. No lithium needed even.
The roadmap for LFP is 230 wh/kg in mass production later this year. 200 wh/kg is already scaling up.
The roadmap for Sodium Ion is 200 wh/kg in a year or two, we'll see on that.
And once sulfur-based chemistries come online, which are allegedly 2-3x as dense as NMC, look out. That means battery packs that are 45% to 30% of the size of previous ones.
Also, yes batteries aren't junk when they need to be replaced. There will be a couple options:
1) the pack is likely 60-70% capacity of the original. It can be used for home powerwalls, grid storage, etc.
2) the pack can be torn apart and individual cells tested/harvested that still function, and those are reintegrated in other uses (lawnmowers? Power tools? powerwalls? Batteries are useful EVERYWHERE).
3) Recycle the whole pack to get the materials / metals back.
That's what is interesting about battery packs. They don't catastrophically die typically. Their EoL is a gradual failure, but they are still useful. Can an ICE engine near its end of life be torn up into hundreds of little engines and repackaged into toys, tools, security cameras, leaf blowers? No? An EV battery can.
So the battery being a major component cost isn't a total loss, more like a depreciating asset component. It will still have inherent value in many ways, far better than the scrap metal value of an engine from an ICE drivetrain.
The battery will degrade, that's how the laws of physics and chemistry work. But the degradation is perfectly predictable and actually (according to historical data) slower than expected. You can buy 10 year old Teslas with 80-85% battery capacity left.
So instead of 450km you can only go for 360km before needing to charge. If you're a hardcore roadtripper who does 1000km+ every weekend just for fun, you can sell it and get a new one. But the average driver doesn't do even 100km per day, they won't care.
https://www.theguardian.com/us-news/2023/jan/24/us-electric-...
As always though, this move is optimizing the wrong thing - we don’t need more efficient cars we need fewer cars. But nobody likes subtractive solutions.
I don’t think politically viable, despite being the real solution to the core problem.
Old US cities only became car centric through massive amounts of pain and hardship, which happened to hit people that were mostly politically disenfranchised. Reshaping in the other direction would involve a similar amount of hardship, but on people that vote. We can make it easier to increase density, but the kind of efforts that would make us not end up relying on EVs have such economic and political costs that we lack the state capacity to go there.
Idk. How much remains usable if it’s under water? Should we let people in Florida tax the rest of the country for their road development? Can Florida afford to maintain and build the roads they want to build?
> Old US cities only became car centric through massive amounts of pain and hardship, which happened to hit people that were mostly politically disenfranchised.
Can you elaborate on this? How are you accounting for highway development that destroyed minority neighborhoods in this assessment?
South Florida will never be underwater. The government would build massive levees around the entire state before that happens.
> How much of, say, Suburban Florida remains usable if we price cars high enough to make their use unadvisable?
We'd just build the right transportation so that this doesn't matter.
This shifts the focus of problems from many different places to one. In the article you linked, it mentions alternatives to reduce lithium needs including smaller batteries, and battery recycling.
This is much easier to regulate, and there is plenty of time to do so - although yes this is putting some trust on governments doing the right thing.
If somebody is even half serious about these concerns, they had better be advocating for extreme reduction in car use. Otherwise it's pure hypocrisy.
The problem is not in EVs, it's in private automobiles, our settlement patterns, and our utter lack of funding public transportation in all of its forms.
It is just as naive to think the US can remake its transportation infrastructure to be like Europe, as it would be to expect every road in Italy to be made wide enough for a Ford F-150 Raptor. Places in the US with high population densities (NYC, DC, Chicago, SF, etc) often do have far better public transportation than the rest of the US.
This is a silly comparison though. Large swaths of the US are either completely uninhabited or nearly completely uninhabited.
If you want a better comparison, look at New Jersey. Its population density is 488 people per km^2, so a little higher than the Netherlands even, yet its infrastructure is dismal comparatively despite having the density to support Netherlands-style infrastructure. Almost all major population centers in the US look like this -- dense enough to support much better, but yet we don't have it. The fact that it wouldn't work in the vast rural expanses of e.g. Wyoming don't mean that it wouldn't work for our big metropolitan areas.
Lithium deposits are geologically widespread and abundant, but 95% of global production is currently concentrated in Australia, Chile, China and Argentina. Large new deposits have been found in diverse countries including Mexico, the US, Portugal, Germany, Kazakhstan, Congo and Mali.
There are massive Lithium deposits at the salton Sea in souther California which are just bubbling up out of the ground in heated brine, meaning the earth is doing most of the work bringing it to the surface as mud. Refining it will need significant water, either from contested supplies fed by the Colorado river or as-yet-unbuilt water pipelines from desalination plants at the coast. But these deposits are massive and the extraction part of the process would have minimal environmental impact compared to the open-pit mining required elsewhere. It's odd that this article doesn't mention this at all.
I have a hard time envisioning that the impact due to lithium mining for one battery pack is worse than the extraction and pollution from burning ~150 barrels of gas. Plus another 3 barrels of motor oil from oil changes.
Not to mention, they are forecasting out over 25 years, on a technology that has been rapidly changing, and is seeing immense investment. Batteries from 15+ years from now will have very different chemistries, and lithium will likely have safer sources. The Chevy EV1 launched with lead-acid batteries about 25 years ago - modern EVs aren’t remotely similar.
"However, reports from Nikkei[1] and Reuters[2] attribute the decision to the automaker's slow response to a rapidly changing automotive industry, specifically the adoption of electric vehicles. "
[1] https://asia.nikkei.com/Business/Companies/Toyota-s-Akio-Toy...
[2] https://www.reuters.com/business/autos-transportation/toyota...
and more
https://www.bnnbloomberg.ca/toyota-appoints-lexus-chief-as-c...
https://uk.finance.yahoo.com/news/toyota-replace-akio-toyoda...
Koji Sato (his replacement) is currently head of Toyota's racing and luxury car divisions. Nothing about this move indicates it is specifically about EVs.
I get that Toyota is still really late with an EV option, but their PHEV selection is still probably best in the industry and they can't make enough of them to keep up with demand.
I think the idea that they should start taking away resources from cars that are already beloved and selling well to (potentially) throw away their reputation on trust and reliability seems incredibly short sighted.
And given that they are the number one seller of cars in the world, incremental improvements in fuel efficiency fleet wide seem like a much better use of their time than providing a gimmicky electric model just for California.
The Model 3 has had 10 years to work out the kinks, the id.3 has had 5 and the Corolla EV is brand new.
Which would you choose? Lots of people would pick the Corolla, expecting it to be the most reliable, well engineered and well built.
Toyota can be late to the EV party and still succeed, a luxury other makers without their reputation and experience do not have.
The b4zx is evidence against this thesis, but I don't think it invalidates it.
It's more expensive than others in the same category, it has worse range, no battery heating - or preheating, only two fast charges per day. And even the "fast" charging is at under 5kW levels if it's even close to 0 C outside.
Why would I pay over 10k more for that instead of a Model Y or Ioniq 5?
1: How much does it cost to run and operate a hydrogen refuelling station?
As a reference: we have been building these since 1999, we should know this now and it should be 100% clear.
2: How many hydrogen cars can you refuel in a row? What happens when you reach the limit?
3: How is the hydrogen delivered, how often and how much does it cost?
4: Can hydrogen stations operate normally in northern winter conditions?
5: What is the normal operational age for hydrogen stations?
6: Where can I find a winter test for hydrogen vehicles? Cold starts from proper frozen conditions (-25C)
2 - Same as a CNG or LPG station
3 - Either via pipelines or tanker trucks. The former is cheaper, although for more remote stations the latter is more practical
4 - Yes
5 - Same as a CNG or LPG station
6 - Here is an example: https://www.press.bmwgroup.com/global/article/detail/T037181...
2. Actual numbers and sources please?
3. Who will construct and pay for these pipelines, since you can't use CNG/LPG pipes for hydrogen?
4. Actual sources please?
5. https://www.hydrogeninsight.com/transport/german-city-to-ret... and https://www.bloomberg.com/news/articles/2022-10-19/shell-clo...
6. Ahh yes, BMW press release about BMW testing a BMW car themselves. Totally neutral and unbiased. Toyota had the same thing, they preheated the car before each run because fuel cells really don't like freezing.
For instance, hydrogen can be made to flow through natural gas pipelines with only minor modifications: https://assets.siemens-energy.com/siemens/assets/api/uuid:3d...
It can be extrapolated that fuel cell cars will similar in most aspects to CNG and LPG powered cars which also have to deal with pressurized gases.
A lot of the anti-hydrogen articles are paid marketing from competing technologies. They are basically not stories at all. FUD is more accurate.
> Ahh yes, BMW press release about BMW testing a BMW car themselves. Totally neutral and unbiased. Toyota had the same thing, they preheated the car before each run because fuel cells really don't like freezing.
Considering that they are actually selling these cars, they are not going to lie about real world performance. Independent testing have found fuel cells to work better than batteries in cold weather: https://www.sustainable-bus.com/news/the-effect-of-cold-weat...
But what I'm worried here is what happens if I park my Hydrogen powered BMW next to my ski holiday cabin in -30C weather for a week, will it still work after that? Does it keep the fuel cell above freezing at all times somehow? Or can it dump the produced water out of the cell so it freezing and expanding doesn't break anything?
But it does seem like the Mirai should be able to start: https://insideevs.com/reviews/460274/2021-toyota-mirai-test-...
Gasoline engines will start if the engine is in good order and the 12V battery has enough juice to crank the engine to get a proper spark.
Diesels will have some issues because the oil is too thick when frozen, but if the 12V battery is in good shape you'll usually make it. You do need to run it for a good while to warm everything up before actually moving.
A hybrid (non-PHEV) Prius will start like it's a summer's day. It uses the drive battery + engine as a starter motor, so it'll just go. The oil in Priuses is so thin it doesn't really change viscosity due to weather that much.
EVs have zero issues. Step in, push button and it'll take about 4-5 minutes for it to be nice and warm inside without any preheating.
Sauce: have started all in -30 to -35 weather every winter.
I'm actually excited for the biggest motoring magazine over here to do their winter test on a Hydrogen car. They don't pull punches for anyone - Teslas for example have huge issues with heating during extreme colds, some valve in the engine freezes over and the heat never gets in the cabin.
There are a TON of winter tests for journalists, all organised by the car maker. There are also a bunch of buff articles and videos about hydrogen cars in cold weather conditions.
Also manufacturers aren't pushing H2 cars too hard in Canada or Nordics/Scandinavia either. It's all just Californian sun or the parts of Europe where -5C is especially cold.
And Toyota's recent announcements that they were seemingly going to put off ecar dev until we were all underwater was pretty incredible even knowing their hate for electric
So this move is prob going to save millions of lives
At least