Toyota’s hydrogen-powered Mirai has experienced rapid depreciation (opens in new tab)

Agreed on "green steel".

In general, "green hydrogen" makes the most sense if used as a chemical feedstock that replace natural gas in industrial processes - not to replace fossil fuels or be burned for heat.

On paper, hydrogen has good energy density, but taking advantage of that in truth is notoriously hard. And for things that demand energy dense fuels, there are many less finicky alternatives.

I had to Google what is green hydrogen. It is hydrogen produced by electrolysis.

If you've already got the electricity for electrolysis, would it not be more efficient and mechanically simpler to store it in a battery and power an electric motor?

Sweden has very little natural gas in its energy mix:

https://ourworldindata.org/grapher/energy-consumption-by-sou...

I highly doubt that hydrogen heating was ever considered. It's usually pushed by the gas lobby (since most hydrogen comes from gas), and Sweden doesn't have a strong gas lobby.

That was extremely stupid of them then. Hydrogen has been very good at one thing: subsidy extraction. But I don't think it was or ever will be a viable fuel for planetary transportation.

> , and thus at some point green hydrogen would be too cheap to meter.

Even if you assume that is true. It will always be more expensive then straight electricity.

> The more sensible project were the green steel project.

Not sure I agree. I think Boston Metal solution is better long term carbon free steel solution.

> natural gas with bio fuels

There was a huge 'bio' fuels hype around like 15-20 years ago if I remember correctly. Huge amount of controversy and false claims with politicians support.

Funny how this now comes back again and nothing was learned.

The idea was to transition from coal to natural gas while using solar and wind to reduce fuel consumption, thereby significantly reducing CO2 emissions. Any claims of hydrogen being burned were either lies to the public to get the gas plants built despite the non-green optics or lies to investors as part of a fraud scheme.

Good context. It's a shame none of these people did high school chemistry.

I do remember there being some news about the steel manf.

I wonder if further advancements in rocketry are adding H2 tech that could help us manage the difficulties of dealing with the stuff. It still only makes sense in very specific circumstances. Like when you need energy in tank form.

But I think battery / biofuel is the future.

Yes, it's not the new oil, it's the same oil in "green" packaging. Plus some comforting lies about carbon capture.

Same with nuclear. The most expensive form of electricity generation there is. No grid operator wants to touch it, but the nuclear industry has been very busy lobbying congress and both the current and last administration.

Carbon Dioxide is a greenhouse gas, which makes the world warmer on average. It also lowers the PH levels of the oceans.

If the oceans die, its very likely that many or even most humans will also. As a human I am pretty strongly opposed to dying, but thats just, like, my opinion man.

We live (or at least used live) in a very nice climate equilibrium with the CO2 level we had. Pushing us into another climate equilibrium looks very dangerous for human civilization. However I concede that it might be advantageous for certain plants, but I am not a plant so I am mostly concerned about human civilization.

The problem is all the effort = energy you need to spend collecting carbon atoms.

> Synthetic fuels (including hydrogen) do still make a lot of sense for heavy stuff like trucks, buses or trains

Synthetic fuels don't "make a lot of sense" for "heavy stuff", rail electrification has been the norm everywhere the capital costs were justified (it's at about 30% worldwide, 57% in europe, some countries like Switzerland are nearly 100% electric).

Synthetic fuels make sense for autonomy reasons when you can't tether the "heavy stuff", but fuel engines absolutely suck for heavy work loads, electric transmissions started being a thing before railway electrification even was.

And of course those are situations where hydrogen sucks, fuel is useful there because it's a stable and dense form of energy storage which is reasonably easy to move about without infrastructure, you can bring a bunch of barrels on a trailer, or tank trailers, to an off-grid site and fuel all your stuff (including electric generators). With hydrogen you're now wasting a significant portion of the energy you brought in trying to keep the hydrogen from going wild.

Trucks and busses would be better off with battery swaps at depo like electric forklifts do. More mileage more towing weight for trucks, just stack more batteries. Overweight? Use a diesel.

Trains is an easy one, over head lines.

Aircraft, I think short distance trips <1hr maybe otherwise biofuel. Likely we’ll see biofuels widely used by 2040. Electric motors on a 777, I’m not sure.

Reality already caught up with synthetic fuel for buses.

Shenzhen electrified its entire 16,000-vehicle bus fleet in 2017 - that's almost a decade ago. Since then virtually all of China has transitioned to electric, and other countries aren't far behind. Electric buses have completely taken over the market.

And it isn't just rich Western countries playing around either. We're seeing countries like Slovenia and Romania at >90% electric, and even countries like Ecuador and Colombia and targeting 100% electric in 2030 and 2035!

All the hard technical and financial problems have been solved. If your city isn't adopting electric buses yet, it will be solely due to political reasons.

> trucks, buses or trains

Trains no, electrify everywhere is clearly better. Maybe for really old legacy branch lines, batteries.

Trucks should as much as possible move to rail, much better solution.

For the rest, the waste majority of short-haul trucking, should be electric. In Europe, the amount of stopping trucks have to do already can be used to charge.

Only ultra long haul trucking has to stay on traditional fuels, and that a small %. And then you might as well just use conventional fuels.

Some aircraft is the only really good application. But I think not hydrogen, and instead syn-jet fuel.

> the place hydrogen might work is airplanes where the energy density of batteries doesn't work.

How is that going to work? Cryogenic liquid hydrogen? High pressure tanks? Those don't seem practical for an airplane.

What does work for airplanes is to use carbon atoms that hydrogen atoms can attach to. Then, it becomes a liquid that can easily be stored at room temperature in lightweight tanks. Very high energy density, and energy per weight!

(I think it's called kerosene.)

Has the hydrogen storage problem been solved yet?

Last time I checked it needs to be stored in cryo / pressure vessel and it also leaks through steel and ruins its structural properties in the process.

WTF , you are commenting about FCEV - these things dont have engines!

The strategy clearly stated by Akio Toyoda is multiple power train technology. You can listen to his interviews on the subject, some are in Japanese, but as you have stated a clear and unambiguous interpretation of Toyota's policy I will assume you have that fluency.

(Automotive OEMs are assemblers, the parts come from the supply chain starting with Tier 1 suppliers. In that sense TMC does not do "making engines", but possibly the nuance and consequences here of whether not it "wraps it's head" to "makes things", vs if it has the capability to specify, manufacture distribute something at scale with a globally localized supply chain AND adjust to consumer demand/resource availability changes 5 years after the design start - in this context i ask you, can you "wrap your head" around the latest models that are coming out in every power train technology fcev, (p)hev to bev)

Biofuel makes more sense for airplanes. No conversion even necessary. You could fuel up a 737 with properly formulated biofuel and fly it now, though a lot of validation would be needed to be generally allowed especially for passenger flights.

If we want easier to produce biofuels then LNG aviation makes sense. We are flying LNG rockets already. You could go ahead and design LNG planes now and they’d emit less carbon even on fossil natural gas. Existing turbofan jet engines could be retrofitted to burn methane.

Biogas is incredibly easy to make to the point that there are pretty easy designs online for off grid biogas digesters you can use to run a generator. You can literally just turn a barrel upside down in a slightly larger barrel full of water, shit, and food waste, attach a hose to it, and as the inner barrel floats up it fills with biogas under mild pressure that you can plug right into things. May need to dry it for some applications since it might contain some water vapor but that’s not hard.

Industrial scale biogas is basically the same principle. Just large scale, usually using sewage and farm waste.

LNG rockets also mean “green” space launch is entirely possible.

> It's coming from Toyota because Toyota can't wrap its head around not making engines.

Of course they can. Toyota sells BEVs. As time goes on BEVs will become a greater percentage of their sales.

We're actually not that far off.

Right now, liquid fuels have about 10x the energy density of batteries. Which absolutely kills it for anything outside of extreme short hop flights. But electric engines are about 3x more efficient than liquid fuel engines. So now we're only 3x-4x of a direct replacement.

That means we are not hugely far off. Boeing's next major plane won't run on batteries, but the one afterwards definitely will.

> It's coming from Toyota because Toyota can't wrap its head around not making engines.

Which is also the reason why its plug-in hybrids are so reliable, despite being dramatically more complex than either an EV or an ICE.

Toyota is very good at making engines, and it would be insane to throw away all that expertise to deliver a half-assed new product.

The energy density doesn't work for now. Everybody hoping for that breakthrough, and battery aircraft are moving into certain sectors (drone delivery, air taxis etc).

It might also be because the Japanese government works very hard to have full employment and EVs require less labor.

What does this mean? They have electric vehicles too.

They are just too much in bed with big oil to want to switch, instead they spend rnd on hydrogen in order to mess up with renewables on purpose.

The Mirai is a fuel cell EV. There is no engine. Not sure what your point is regarding engines?

Ehh, the Hindenburg had a flammable skin. Barrage balloons from the World Wars were most often filled with hydrogen and yet were extremely difficult to ignite or take down even with purpose build incindiary ammo for that purpose shows hydrogen balloons can be safe. Often they would be riddled with dozens of holes but still take many hours for them to lose enough hydrogen to float back down to the ground.

The only real downsides are slow travel speed and vulnerability to extreme storms since there arent many places to put it with a large enough hanger even with days of warning beforehand.

Pointing to the Hindenburg as an example of why hydrogen is a bad idea is the same as pointing to Chernobyl as an example of why nuclear is a bad idea.

wait...

Politicians are conduits. Someone wanted this to happen.

But yea, subsidies. I've been on many a call where "there's govt funding available if we shape this like x" is one of the major selling points.

No . No . No. Please No. Absolutely fucking not.

Shipping hydrogen is literally one of the dumbest things you can ever do.

Its pure and utter nonsense that is only getting pushed for political reasons. It has 0 actual viability.

Even if you were willing to pay 5-10x more for hydrogen, shipping doesn't make sense.

The only way we are ever moving any quantity of hydrogen anywhere is with pipelines. Literally everything about hydrogen makes it a complete nightmare to ship.

And nobody is likely ever going to build these hydrogen pipelines.

Hydrogen is completely idiotic as a 'energy move' medium.

> Using it as a car fuel only makes sense as an interim step to full renewable/EVs.

No it doesn't and it never did. Only such a tiny amount were ever sold, and those were only sold because of massive subsidies and sold below value by car companies who wanted to push the concept (and farm subsidies).

EV by 2008 already outsold hydrogen vehicles and have grown every year, hydrogen vehicles never became more then marketing gimick and were never sold in numbers that even approach relevance.

Also the losses are much higher when converting electricity to hydrogen and then burning that hydrogen.

Really, they shouldn't be punished, they should be rewarded if they can become more sensible.

Positive incentive please :)

That is how EVs got here as soon as they did.

Ignoring some of the other issues:

Imagine we have this electrolysis plant, splitting up water to produce the hydrogen we need for an area. That's fine.

But it needs fed electricity to keep the process going. Lots of it. It needs more electrical power to split the water than combining it again produces.

So it starts off being energy-negative, and it takes serious electricity to make it happen. Our grid isn't necessarily ready for that.

And then we need to transport the hydrogen. Probably with things like trucks and trains at first (but maybe pipelines eventually). This makes it even more energy-negative, and adds having great volumes of this potentially-explosive gas in our immediate vicinity some of the time whether we're using it individually or not.

Or: We can just plug in our battery-cars at home, and skip all that fuel transportation business altogether.

It's still energy-negative, and the grid might not be ready for everyone to do that either.

But at least we don't need to to implement an entirely new kind of scale for hydrogen production and distribution before it can be used.

So that's kind of the way we've been going: We plug out cars into the existing grid and charge them using the same electricity that could instead have been used to produce hydrogen.

(It'd be nice if battery recycling were more common, but it turns out that they have far longer useful lives than anyone reasonably anticipated and it just isn't a huge problem...yet. And that's not a huge concern, really: We already have a profitable and profoundly vast automotive recycling industry. We'll be sourcing lithium from automotive salvage yards as soon as it is profitable to do so.)

It’s horrible to work with - dangerous, embrittlement issues etc., and very energy intensive to compress into very heavy cryogenic storage containers…

It's hell to store. The energy density is terrible and as a tiny molecule it escapes most seals. When it transitions from a liquid to a gas, it expands manyfold (i.e., explodes).

Zubrin's "Hydrogen Hoax" from 2007[1] is basically an ironclad critique. The physics are inescapably poor, and always will be. (Zubrin makes other points in that article which should probably be taken with more salt, but his critique of hydrogen stands).

1: https://www.thenewatlantis.com/publications/the-hydrogen-hoa...

Besides being expensive to generate unless you already happen to have an electrolysis plant handy, hydrogen is awkward and hazardous to store. Once generated, it costs yet more energy to liquefy, and then it seeps right through many common metals, weakening them in the process. It's just not a good consumer-level energy source, and nobody could figure out why Toyota couldn't see that.

Interestingly, liquid hydrogen is nowhere near the most energy-dense way to store and transport it. I don't recall the exact numbers but absorption in a rare-earth metal matrix is said to be much better on a volumetric basis. [1] Still not exactly cheap or convenient, but it mitigates at least some of the drawbacks with liquid H2.

1: https://www.fuelcellstore.com/blog-section/what-hydrogen-sto...

>you've got a very high-density, lightweight fuel.

Correction, a very low density, lightweight fuel.

Burns clean though with no carbon in the exhaust.

But the upstream carbon emissions have not come close to zero when you look at total hydrogen use in the real world so far.

Check out the "Clean Hydrogen Ladder" document.

Hydrogen wastes a large amount of energy.

The cheapest way to make hydrogen is to use fossil fuels.

Hydrogen is the minimum viable atom: one proton, one electron. H2 is a tiny molecule. "hydrogen embrittlement" is when it's small enough to diffuse into solid metal, because it's that much smaller than iron atoms.

It's hard to work with because of this, and what's the point? For most uses, electricity supply is already everywhere.

The part that's interesting to me is how much the depreciation is posed as negative rather than positive.

The long term value of a car is only really relevant if one is constantly cycling through cars and needs the trade-in/resale value. If a car isn't viewed as an investment and/or the intention is to drive it into the ground, depreciation is purely positive because it means that there's insanely good deals on some great cars right now. Of course everybody's needs are different, but for a lot of people there's nothing that comes remotely close of the value of a gently driven, practically new 1-3 year old lease return EV.

EV depreciation is a very different beast. Basically, EVs are still being sold at a higher price point than their actual cost justifies in some markets. Part of that is manufacturers being a bit behind on their cost cutting and part of that is just because the market is incentivizing selling vehicles at inflated prices.

If you strip that away, you get to more reasonable price points already getting common all over Asia, Australia, and even the EU market right now. There you might find reasonably priced new vehicles at around 25K euros or even below 20K. A few years ago, those vehicles didn't exist and ASPs were closer to 40-50K for a cheap one. So, the second hand value of those older vehicles has indeed depreciated enormously. Because they simply are not worth as much relative to the much cheaper newer generation of cars. These vehicles got obsoleted by a better and cheaper generation of cars.

With hydrogen cars, companies sell them at a loss. They always have. That's why Toyota, the biggest proponent, sells more EVs than they ever built hydrogen cars. Pretty much every quarter now.

The better/cheaper generation of hydrogen cars never materialized. And it probably never will. The hydrogen distribution network never happened either. Because as it turns out, making hydrogen is really expensive. So aside from a few heavily subsidized filling stations, the economics for those is so terrible that they tend to shut down as soon as the subsidies run out. So, that's why they are relatively worthless as a second hand car. You are better off buying a second hand EV. And since those have depreciated a lot, hydrogen cars simply aren't worth more second hand.

And since there is no realistic prospect of ever producing hydrogen cars or hydrogen at price points that can match those of EVs and electricity, hydrogen based transport is at this point dead as a door nail.

My state assesses annual car taxes based on MSRP rather than real market value, unfortunately, so these fake MSRPs matter to me. :-(

Depreciation is measured against the price someone actually paid.

The MSRP doesn’t matter. The S stands for suggested.

still means nothing, what is the mileage or $/mi there?

Full tank capacity of a Mirai is ~5 kg / (120 liters in volume).

Forget the type of electrolyzer, even if they were free hydrogen would still be expensive. The challenges with hydrogen getting cheaper are thermodynamic and can’t be innovated around. The amount of energy required to electrolyze water simply cannot drop by 10x.

The other difficulties (low energy density, ability to leak through many materials, massive explosion risks, near-invisible flames, etc., etc.) are all inherent to H2 as a molecule.

I'd assume because it is complicated. Capturing enough carbon, splitting it, generating enough H2, combining it with the carbon to make long enough chains. That all sounds complicated and expensive and probably needs even more surplus green power that we don't have. It also doesn't solve the problem of local pollution when burning carbon based fuels.

Completely wrong.

Globally over 95% of hydrogen is sourced from fossil fuels, particularly natural gas wells. Electrolysis is very limited to niche applications or token projects.

That’s not a thing. Anyone who’s seen hydrogen being split from electrolysis knows it takes a lot lot lot of electricity and is very slow. If two people needed to fill up in the same day it would run the well dry.

If you can do that at a meaningful rate you might as well install ev charging and just not electrolyse when cars are charging

Your understanding is entirely wrong.

Most hydrogen fueling stations receive it from the next steam reformer, which will make it from fossil gas.

this is the case while they're in the hype building phase, when people are paying attention

if hydrogen even gained widespread adoption, it would be mass produced via steam reforming of natural gas

(which is why the oil majors are the ones desperately pushing it)

Okay not driving it around then. But somehow it's worse. You still have to build the special tank and the special pump and also get an electrolysis device that is big enough to create enough hydrogen and also you have to get heaps of power somewhere that could instead be just straight put into a battery in a car. Make it make sense. What's the point? Who is willing to do that?

Isn’t this bad? This means H2O molecules are being destroyed and the water is not returning to the water cycle to be reused. We will literally run out of water if everyone did this.

These problems are grossly exaggerated in popular discussions. Hydrogen has been routinely transported and stored in standard steel cylinders for over a century. Most cities originally used coal gas (50% hydrogen by volume) for heating and illumination before switching to natural gas after World War II. What kills the idea is the abysmal efficiency of electrolysis and hydrogen fuel cells. Standard high-voltage DC power lines would be much better suited for getting solar power from Arizona to Alaska.

Storage is the bigger problem, specifically very long duration or rarely used storage (to cover Dunkelflauten, for example) for which batteries are poorly suited. Hydrogen (or more generally e-fuels) is one way to do that, but another very attractive one is very low capex thermal storage. Personally, I feel the latter would beat hydrogen: the round trip efficiency is similar or better, the complexity is very low, power-related capex should be lower, and there's no need for possibly locally unavailable geology (salt formations) for hydrogen storage.

With this sort of storage, Alaska in winter gets its energy from Alaska in summer.

Moving renewable power is easy, we have a grid for that. Infrastructure for movement of electricity is ubiquitous in places that have never seen a hydrogen pump.

If the grid is insufficient in a particular place or corridor, investing in upgrading it will provide a better long term solution than converting electricity to hydrogen, driving that hydrogen around on roads, and converting it back into electricity.

Storage is a bigger issue for sure.

Only if we had a true oversupply of green energy. Converting electricity to H2 and then back is so incredible inefficient. It's less work to just create better electrical transmission systems. China did that with their high voltage DC lines.

At that point you're just building a weird battery storage system again though.

Maybe if we had smartphones that emitted greenhouse and toxic gases by using a mini ICE engine that were so cheap nobody would buy anything else, we would subsidize the electric ones. We may even ban the gas phones.

We also wouldn't need to if environmental externalities were costed into petroleum prices.

I am not comparing BEV with ICE. That would be stupid. ICE is not and will never be a solution to the fact that we are burning oil and destroying the environment. But EV has to compete with ICE and many people don't like the fact that they might be a small inconvenience. The environment is just not part of the calculation so to make BEVs even slightly competitive the price has to be lowered.

H2 doesn't compete with ICE. It competes with BEV. That and in that comparison I do think it is much simpler. I'd be open to be enlightened why the killer feature of H2 is that makes it even worth considering with all these downsides.

> we shouldn't have to subsidize electric cars either.

Smart phones were subsidised, just less obviously. Much of the fundamental research into the radio systems was done by government labs, for example.

Not to mention that governments provide maaaaasssive subsidies to the entire fossil fuel industry, including multi-trillion dollar wars in the middle east to control the oil!

Look at it from the perspective of pollution control in cities. China just invested tens of billions - maybe hundreds — into clearing out the smog they were notorious for. Electric vehicles are a part of the solution.

The alternative is everyone living a decade less because… the market forces will it.

ICE love is cultural, and there's a bunch of FUD from entrenched interests.

Still seems like a smaller investment to get a bigger cable than H2 infrastructure (Tanks, Pumps, maybe even electrolysis system).

True, but they already exist.

Hydrogen stations don’t. If you have to build new ones, especially if you have to supply them with enough power to create their own hydrogen for water, what’s the difference from just building EV chargers?

And if you’re going to add hydrogen to existing gasoline stations then same question.

If hydrogen was somehow able to use existing gasoline infrastructure it would make a lot more sense. But it’s not.

Well… I did/do see many around the Bay Area. Especially during the morning commute. But I agree, overall it was a low volume car.

Funny thing, Air Liquide. They were going to build a massive green hydrogen plant in upstate NY and backed out when the tax credits disappeared...

https://www.airproducts.com/company/news-center/2025/02/0224...

EVs are cheaper to own – the fuel savings are enormous.

EVs aren't cheaper to produce yet, but battery costs are still falling and they will reach parity with ICE vehicles soon.

My EV has cost me ~$1,100/yr less to operate over the last few years for the same mileage compared to my ICE, and I didn't even have any major issues with my ICE. Meanwhile its been charged with almost exclusively 100% renewable, zero-emission energy.

You're both wrong, the Mirai uses a fuel cell as the voltage source for an otherwise EV drive train. The Mirai is an EV with a fuel cell instead of a battery.

There is no ICE in a Mirai.

>Is it? Then why isn't it cheaper to produce and cheaper to own?

Because batteries are very expensive. But they aren't particularly complex.

This argument just does not make any sense at all. Of course simple components can be more expensive. The cost of ownership is even less relevant, since it depends almost entirely on outside factors, which vary by region and government.

>It's a standard combustion engine, nothing special.

This is totally false. The hydrogen storage alone is enormously complicated. Hydrogen, especially at the pressures needed for a car to be viable is far more complex to store safely then fuel storage for a regular diesel/gasoline car.

Pretending this is not the case is just delusional.

I think there's some truth to this. Toyota desperately needs the future to play to their strengths, something more complicated than EVs, which I think is behind their obsession with hybrids.

Not sure that a fuel cell vehicle isn't just an EV with extra steps, however.

The latest model comes with a li-ion battery pack. Previous model had Nimh cells I think.

In fairness, hydrogen from gas would enable the CO2 to be sequestered. If the vehicle itself burned the natural gas that would require recapturing the CO2 from the atmosphere itself, which is much more challenging.

None of this is to detract from the attractiveness of battery vehicles.

How do you solve aeronautical and maritime applications?

Carbon doesn't really contain all that much hydrogen.

Feasibility is key.

https://www.youtube.com/watch?v=1GSV2kVkO1w

That program was not available in my region

And they are not even supposed to explode anymore!

Looking at Ford Mach-E. I don't see the number you are seeing. I can find 2024 Mach-E 50% off its MSRP.