> Here we report a catalytic system composed of 1-ethyl-3-methylimidazolium-functionalized Mo3P nanoparticles coated with an anion-exchange ionomer that produces propane from CO2 with a current density of −395 mA cm−2 and a Faradaic efficiency of 91% at −0.8 V versus reversible hydrogen electrode over 100 h in an electrolyser.

This is almost too good to be true... they demonstrate commercially viable reaction rates, efficiencies and timescales.

They have presumably applied for a patent for it, so in 20 years when the patent expires this will become the standard thing to do with recovered CO2 I'd guess.

Well, only if the patent-holder makes no effort to maximize the return on its investment in those 20 years. But if the technology is really that effective and the patent-holder is even a little bit economically rational, then presumably the patent holder will be the one pushing hardest to make this the standard thing to do with recovered CO2 well before the patent expires.

Not that patents are all roses and puppy dogs. But this is too big a part of the picture to just ignore.

No they've decided to go the route of tobacco companies, deny everything and party while the sun is shining. By the time the lawyers show up they're counting on being dead or too old to stand trial.

You... you're aware that the actual, historically realized, attitude of fossil fuel companies has been to deny any harm exists, right? Deny it to the tune of 200 million dollars as recently of 2019, and for good reason! That spending bought them lots of political inaction since the science was settled in like 1990, you know: the days where keeping staying below 1.0 degrees warming was a realistic goal.

CO2 conversion tech is a path to selling more fossil fuels.

Could you please not.

You are presenting a false dichotomy. It’s not “bribe vs. use this tech”. It’s also not really about bribing at all. Fossil fuels are important. That sucks, but we do need them in the short term.

If this tech works, and the government is willing to pay for it to some extent, it’s probably a lot cheaper to build caseload gas plants and peak daytime load renewables than it is to try and build excessive green power and batteries to tide the night over.

Or just, you know, worst case run this profitable service independently of externalities

They have a deep incentive to capture the regulatory framework that might hold them accountable for that harm, which they have accomplished.

Look how well that's worked out for the financial sector. Nothing but good faith actors there. Immaculate.

I’m saying that fossil fuels companies are incentivized to sell useful co2 converters because this enables them to sell more fossil fuels.

They have one in this space: "Methods and devices using tri-transition metal phosphides for efficient electrocatalytic reactions" at https://patents.google.com/patent/US20220154354A1/en with abstract:

] Methods and devices for generating hydrogen gas with an electrocatalytic energy conversion cell by introducing a tri-transition metal phosphide catalyst at or on an electrode of the electrocatalytic energy conversion cell. The electrocatalytic energy conversion cell includes a first electrode including a tri-transition metal phosphide catalyst, such as MO3P, a second electrode of an anodic material, an electrolyte disposed between the first electrode and the second electrode, and an electric potential source connected to both electrodes. Oxidation and reduction reactions, such as hydrogen evolution reactions, occur at the first electrode.

(Google Patents says "M03P", the PDF says "MO3P" in the abstract, but the text clearly has "Mo3P".)

Even if this isn't exactly the technology discussed - Supplementary Figure 20 shows how ImF-Mo3P catalyst improves on "pristine Mo3P nanoparticles" - the authors have several other related patents, so I have no doubt a patent was filed for this technology as well.

EDIT: note that burning that propane in a cheap generator is only gonna net you 10MJ/kg of electricity, maybe 17MJ/kg in a large expensive generator. So the roundtrip efficiency is just 9-15% efficient. But it potentially saves you a LOT in storage costs if you’re only cycling this storage once or twice a year.

(Note that propane is a great way to store hydrocarbons as the pressure is low but it’s self pressurizing and thus it doesn’t get water ingress or have any of the storage difficulties of gasoline and diesel, which last only 3-6 months or 6-12 months respectively. It’s also very clean burning compared to those two.)

50% is almost exactly the paper's claimed efficiency for the lab cell, so it's a reasonable number.

Overall, I'm very enthusiastic electrocatalytic methods for producing hydrocarbons as a combustion fuel source for applications where direct electric technologies are not feasible. I'd much rather seen money and energy going into making something like this work, than all the effort on hydrogen. Propane, or any hydrocarbon in the 3C-8C range, is a way better fuel for any fossil fuel replacement energy system than hydrogen.

With batteries storing that is technically possible but it would take the whole world decades to build the required infrastructure.

With propane or other similar hydrocarbons it's around 2 million tonnes. 4 million if you account for 50% efficiency of turbines (we have better ones BTW).

4 million tonnes of gas seems like a lot, but currently USA has about 5850 bcf (1.6*10^14 liters) of underground gas storage ready, at 1.8 kg per m3 you could store about 300 million tonnes of propane. Enough to power the electricity grid of the whole world for 75 years.

So it's a choice between spending billions and turning our whole industrial output to it for years - or just using a fraction of what's already there in a slightly different way :)

Another point is - once you have one kind of hydrocarbons - you can burn them in adapted ICEs or transform into other hydrocarbons to be able to use existing cars. Suddenly you can continue to use the whole infrastructure we built in the last 100 years as if nothing happened with net 0 carbon footprint.

It's the only thing that makes sense, really.

Propane has a thermal energy content of 13778 watt-hours per kilogram [1]. That's (25000 * 10^12) / 13778 = 1,814,486,863,115 kilograms, or 1.8 billion tons. 3.6 billion tons of propane if you recover electricity at 50% efficiency. That would make the 300 million ton underground storage equivalent to one month of global electricity demand. That's still a lot of storage, of course.

[1] https://en.wikipedia.org/wiki/Energy_density#In_chemical_rea...

Thus we should be looking for efficient ways of turning clean energy into hydrocarbon fuel.

Propane is easy to store, easy to transport, propane storage tanks are cheaper than batteries, require no high-tech manufacturing or rare earth elements, and I'd guess the energy storage density is higher.

Many (most) existing cars could be converted to run on propane and the engines will last longer and emissions will be lower as it's a cleaner-burning fuel.

Not that I'm in favor of combustion engines persisting.

This assumes that co2 recapture and propane synthesis require less energy than is produced by burning propane.

This is maybe a workload for excess solar, making renewable propane with electric that would otherwise be wasted

And its cost.

Or more generally, where the catalyst sits in the supply chain (how easy it is to produce at scale, can it be recycled, is it expensive, what is the waste management for it, etc...)

Let's say my car burns equivalent of 100kWh worth of LPG, how many kWh of propane i can recover from the exhaust gas and how many kWh of electricity i need to provide for that?

It's not viable (in terms of energy availability, packaging, or economies of scale) to run that sort of cryogenic high-pressure CO2 purification and storage system on the exhaust pipe of a vehicle. I could maybe imagine a solar installation with this attached being viable at, say, a remote farm with LPG-powered agricultural vehicles, or if I stretch my imagination to scifi timescales (and think about the number of remarkable compressors installed at scale in HVAC systems) to suburban homes with rooftop solar.

https://en.wikipedia.org/wiki/Fischer%E2%80%93Tropsch_proces...

The economics are so awful because of a complex network of reactions, there are processes that build up larger hydrocarbons and break them down and you have to balance these just right to get liquid fuels and not paraffin wax or methane. Some kind of single-entity fuel has always seemed to make more sense to me: methane isn't that good of a destination because it's not that easy to handle or liquefy, propane is quite easy to handle in comparison.

Patents? Nope.

And how many years would it have taken if a patent wasn't an incentive?

If this is meant to use concentrated CO2 coming out from a furnace, would that need to be local, piped in over a long distance, or using bottles? Are there use cases where we must burn propane because we can’t replace that process with electricity?

I think this might slot in everwhere we currently plan to use hydrogen, with the added benefit of larger storage.

Here in Europe we have massive natural gas storage facilities so we can buy gas during summer to use for heating in winter. We will need something similar but renewable. If we can fill that storage with green propane, that would be amazing. It would mean we can keep our heating infrastructure. And we have an amazing use for the solar over-production in summer.

Honestly tho, this sounds to good to be true.

Also saves us from maintaining a residential gas network.

Not only is that going to be expensive and thus impopular. It will also be a delayed transition, and use up an incredible amount of resources.

Not that we should do this instead of heat-pumps. We can do both. Heat-pumps in new houses and if possible when replacing old furnaces.

For all the existing stuff, this could be a great stop-gap.

Trenched gas lines require extensive infrastructure; while each point of use also has electrical service. How is gas less infrastructure?

Apparently decades ago some absolute madman genius decided that we should put down 5 copper cables to every house and building for 3-phase power, even though they only needed one phase for the coming decades.

You know. just in case.

In New Zealand everyone uses heatpumps and there is no problem with everyone running them. Heatpumps don't use a huge amount of power even on cold days. If the grid can handle everyone cooking dinner at 6pm, it can handle heatpumps running throughout the day keeping the house warm.

Fast electric car charging on the other hand draws a lot of current.

Example, a gas furnace runs at 100% efficiency (103% I believe). Heat pump at 300%. Gas to electricity to home goes at 30%. End to end they both perform at 100%. So on efficiency perspective the gas furnace equals the heat pump - but at a much lower cost.

Retaining the gas network saves us from the massive investments needed in the electricity network.

It would surprise me if gas turbines exceed 40% on average, and then the electricity still needs to be distributed. New turbines, probably particularly when using propane could do much better indeed.

My heat pumps all advertise a SCOP of around 5 for heating, and I guess the domestic hot water it would be 2.5 (don't have that, using solar for that myself). And there is a lot the installers can and will screw up, just read some user forums on this. And which consumer actually checks the real COP? So large numbers of heat pumps will perform far from optimal without somebody noticing. The 'screw up surface' of gas furnaces is much smaller. For example, ground heat sources rarely get replenished in summer (not mandatory for residential in my country).

Heat pumps do not make sense unless the energy transition into the equation (wind and solar indeed). But also then, there are major shortcomings with wind/solar currently not yet fixed. For example, my home produces appr. 12 MWh solar energy per year and the heat pumps use a similar amount. Nice balance, but too bad the is a gap of six months between the two.

This post seems to have gotten a lukewarm reception. People are maybe extra sceptical after the lk99 dud.

Yes. Ships, for one - no way you can power an oceangoing large ship with batteries for the entire trip, but doable with LPG (which is essentially a propane/butane mix). Assuming that further technology (chemical or biotech) gets developed to combine it to form larger hydrocarbons, it can also be used as a precursor for airflight synthfuel.

Both Yanmar and Kawasaki are developing large marine four-stroke piston engines for hydrogen, with 2025 as launch date.

Ammonia-fuelled piston engines are easy, their only problem is idling due to the poor combustion properties of ammonia, which you can solve in the pragmatic way by using a little hydrocarbons during idle - combined with power from shore during docking, that still gets you >95% emission reductions.

Ammonia to my knowledge has a problem of both potential toxicity (both if gas escapes in refuelling and NOx emissions after burning) and needing enriched pure oxygen rather than running with atmospheric air.

Propane or other hydrocarbons look superior to both of these to me.

I'm saying that hydrogen is a bad option, but if e.g. this renewable propane turns out to cost $1000/litre then hydrogen wins by default. It wouldn't be that surprising, current synthfuel is expensive AF. And this new headline hasn't been commercialized yet, so it might not be viable after all.

The benefit of hydrogen fuel is that, while it works poorly, it does work and is already in use today, in e.g. forklifts. It was in use decades ago, in fact. It's boring and low-risk, if we can't find anything good.

Hydrogen leaks out of almost everything, embrittles steel, is hard to store as a liquid and needs very high pressures to store a meaningful amount as a gas.

A full EV transition would also free up quite a lot of biofuels. Not enough on its own, but still significant.

To my knowledge wind-powered cargo ships can only supplement cargo ships and can't fully substitute for a proper fuel source, but I would absolutely love to be proven wrong.

The bulk of biofuels are a dead end (although some types of biofuels are valuable in recycling waste products), because modern agriculture basically just turns oil into food; BEV tractors basically don't work due to the range and charging-times needed on an already very heavy vehicle.

I don’t think green hydrogen or synthetic fuel is a realistic option yet. As to a fully wind powered boats, the last fully wind powered cargo boat used commercially lasted until the 1960’s it lost but not by some huge margin. So yes fossil fuels win, but they don’t win by such a huge margin that a fuel costing 4x as much also wins.

Hybrid battery/solar + wind boats are still a common thing for houseboats and pleasure craft in part because of the cost advantages. At even a 2x cost bump over bunker fuel I suspect bulk shipping would start to go a similar route. Militaries and billionaire super yachts might go with hydrogen or synthetic fuel’s it just a question of how quickly their prices fall.

It is going to be some kind of chemical fuel, it is just a question of what and when. The alternative is just people not doing their physics homework and being totally wrong.

Wind is what provides power and scales incredibly far, we already have individual floating 16MW wind turbines. The very largest ships are approaching 60MW, but rarely operate at full power instead “slow steaming” to conserve fuel. https://en.wikipedia.org/wiki/Slow_steaming

The cost of the ship alone is irrelevant if you’re trying to sell fuel at 4x the price almost nobody is going to be willing to pay when they’re not even willing to pay full price at todays fuel prices instead choosing to travel slower than sailing ships while still paying for fuel.

PS: As to battery weight, ships scale really well around weight which is why we have ships moving 200,000+ tractor trailers worth of cargo. There’s fully battery powered ships traveling hundreds of miles for local delivery to remote areas. Which actually means going from Asia to Europe or Africa with some battery swapping is viable. Higher upfront costs and extra stops, but drastically reduced fuel consumption.

You're going to need chemical fuels to solve this problem. You really have to get to grips with basic physics here. Global warming can't be solved by science deniers.

PS: How are you going to battery swap on a ship? Nevermind the cost of such a thing. This is just another absurd idea stacked top of an already absurd idea.

I am not suggesting a wind turbine is an ideal fit for a cargo ship just mentioning how much power we’re already extracting on floating devices that move with the ocean.

Ultra slow steaming is 40% of max power for a 46MW cargo ship that’s 24MW so we’re in the ballpark what comes next is hardcore engineering by companies who understand the industry and they say the math is really close to working at current fuel prices. It’s you who wants people to swap to ultra expensive fuels and I’m just point out that “bunker fuel” > wind but wind > ultra expensive fuels.

Again, the wind turbines you are suggest are far too big for a ship. It is totally impossible. You are not going to get more than a tiny percentage of power from wind from this. At best, you are just going to have literal sails that take off some of the power demand from the engine. The ship will still have to be powered predominately by chemical fuels.

Look, you're flat out denying the physics of this problem. You cannot solve this problem with science denier. You are doing the same thing that climate change deniers are doing.

“Flat out denying the physics of this problem” you’re arguing that sailing ships don’t work.

Maersk the largest shipbuilder in the world already got flettner rotors to provide useful levels of propulsion, ADD a kite system and you’re traveling faster than commercial shipping doing slow steaming. As I’ve said repeatedly they don’t quite work at current fuel prices, but you want to increase fuel prices.. Read up on: https://en.wikipedia.org/wiki/MS_Onego_Deusto for why kite’s didn’t take off it was all about the economics not the underlying physics.

PS: Without paying for fuel the economics changes enough we probably aren’t going to see 200,000+ TEU ships and routes would optimize for winds. But that’s not an inherent problem it’s just a tradeoff, perhaps we invest in larger port’s that just an expense not a deal killer.

This is just you handwaving the problem away. You will need a very reliable supply of energy for this. It actual makes more sense to convert that green energy to something like hydrogen for powering ships. If done at scale, cost will be not much more than the cost of the wind and solar energy itself. Which is potentially very low. And nevermind the fact that you have nowhere near the capacity of batteries to power your ships.

> “Flat out denying the physics of this problem” you’re arguing that sailing ships don’t work.

The largest sailship ever has a displacement tonnage of around 5,000 tons. Modern cargo ships are closer to 250,000 tons. Sailships don't work at the scale you're imagining them. It is basically going back to the 19th century in terms of shipping capacity.

> Maersk the largest shipbuilder in the world already got flettner rotors to provide useful levels of propulsion, ADD a kite system and you’re traveling faster than commercial shipping doing slow steaming.

Skysail just reduces fuel consumption somewhat. It also seem to have disappeared as a serious idea about a decade ago: https://www.ship-technology.com/features/feature-skysails-br...

Solar is extremely reliable as long as you have an oversupply when all you want to to charge batteries. At sub 2c/kWh it’s highly variable but build in 50% extra and you’re only at 3c/kWh and now very consistent across a full week. Obviously, there’s varying tradeoffs so if the cheapest solution is to stick them on a boat and charge em in another country that’s what would end up happening. There’s also obviously tradeoffs between moving shipping containers vs moving electricity but again that’s an optimization problem not some inherent limitation.

Skysail isn’t viable at current fuel prices, the technology works just fine. Current sail designs are of limited value along current routes, but those routes are also optimized for fossil fuels.

Club Med 2 built on 1992 was 15,000 tons and a quite traditional design for aesthetics, again Skysail can significantly boost propulsion. Thousands of economically viable modern cargo ships are 50,000 ton panamax ships and plenty are well below that, those 250,000 ton monsters are an economic optimization between a handful of major ports not some inherent requirement.

The total crew size is largely independent of cargo size, but even relatively small ships are moving 100’s of TEU per worker. At that point it’s only a question of what’s the most efficient design economically not what’s the largest ship.

Seriously, you seem like someone who is obsessed with doing it with batteries, not a person even remotely interested in finding a working solution.

Meanwhile, the alternative, just making hydrogen with the same renewable energy source and powering your ships with it, is sitting right there as an obvious answer. If you already admit to the existence of $0.02/kWh electricity, then the rest of the cost equation is also going to be low here. You've already solved the economics of the issue. The rest is scaling up, and this time there is no need for sails or downsizing ships.

Real world capacity factor Capacity factor 27.9% (average 2017-2019) https://en.wikipedia.org/wiki/Copper_Mountain_Solar_Facility that’s surprisingly close to the theoretical maximum for the location and design. Some break 30% but again it’s not about maximizing output just how much it cost to guarantee we can fill X TEU worth of shipping containers per ~week. Thus it don’t matter if there a 18 hour period one day when they aren’t being charged as long as you can charge enough on average.

> Meanwhile, the alternative, just making hydrogen

Sure let’s pay vastly more per gallon that’s an easy selling point. Hydrogen has maximum limits imposed by physics that severely limit end to end efficiency. It’s a dangerous bitch to store, transport etc. Low density, damages metals it comes in contact with etc, even rocketry got away from the stuff even though it has significant advantages for them.

Nobody is using the stuff because it’s got huge problems.

You've already admitted that solar is just $0.02/kWh. You can do the rest of the math and realize that hydrogen will also be very cheap. You're entirely thinking in cliches now. It is "battery = cheap, hydrogen = expensive" despite your own argument contradicting that claim.

In reality, people will just some kind of chemical fuels. If not hydrogen directly, then something derived from it like ammonia or synfuels. It is already happening in fact, and your obsession simply won't happen.

Look at hydrogen fuel station pricing sometimes even using fossil fuels and compare costs vs bunker fuel. There’s projections it could possibly get close to US gas prices in 20 years, but that includes road taxes, high refining costs, transportation, etc and are therefore much higher than bunker fuel actually used by boats. So the optimistic projections are doubling a ship’s fuel costs and current prices are much higher than that.

As to your “nonsensical idea” complaint, companies actually saving companies money today using it. This isn’t some hypothetical, actual ships on the ocean are using large scale batteries to save on fuel costs. Further, the absolute largest car carrier in the world is smaller than the largest sailing vessel ever built, they load and unload from the front so sticking sails on top wouldn’t be a problem. Fossil fuels are cheap, but hydrogen isn’t viable today which is why ships aren’t using it and it’s not projected to be viable for decades. Anyone who tried using hydrogen would simply be eaten alive by the competition.

The thing about hydrogen is that is made from an extremely plentiful resource: water + green energy. That puts the cost floor at below that of bunker fuel. In fact, the cost floor is pretty close to zero. So you are basically repeating the generic "renewable resources can never be cheap" argument. But it has been discredited.

Nobody uses anything like a battery powered ship for long distance travel. You are making up imaginary scenarios.

Net-zero is nice, but extraction and storage is net-negative.

[0] https://www.npr.org/2023/06/23/1182973358/step-aboard-the-nu...

https://en.wikipedia.org/wiki/Nuclear_marine_propulsion#Civi... comments the major issue is the costs of specialized infrastructure, and points out how research about a modern design concluded "further maturity of nuclear technology and the development and harmonisation of the regulatory framework would be necessary before the concept would be viable."

Nuclear in civilian hands is an absolute no-go for proliferation / terrorism concerns.

https://www.cnn.com/2023/08/22/travel/wind-powered-cargo-shi...

1. Kites attached by cable (deployed, high altitude for consistent winds)

2. Magnus effect cylindrical turbines that rise out of the ship.

Though that was because it was badly mismanaged and the technology wasn't there yet.

Nuclear power plants are much more expensive, and require a much higher (and more expensive) level of labor. These fixed costs are not reduced when full power is not needed.

Put your reactors on land, when the grid has too much power you direct it to something like this (or the hydrogen generator that showed up here a few days ago) and convert it to chemical energy.

That's not relevant in the short term. There are so many things using propane right now and it's a lot easier send them "renewable propane" than to entirely retrofit them to be electric.

I see statements like this every now and then, and I really wonder where that comes from, because that is not at all obvious, and most likely in most cases wrong.

If you imagine that "renewable propane" is something that you can just get, then it may appear easier to use your existing devices. But it's not. It's something that is not produced at any meaningful scale anywhere. There are no industrial processes to do so yet. You're talking about creating a whole new industry using technologies that don't exist yet, and by the way, a new industry that needs massive amounts of renewable energy. A lot more of that renewable energy compared to direct electrification. Nothing about that is easy.

This whole conversation is a hypothetical. Restricting the discussion to only existing technology makes no sense.

As opposed to...replacing every single ICE with an all-electric equivalent. I think scaled up renewable propane would be a much cheaper cost overall than rebuilding every single vehicle in existence.

I don't think you have any realistic idea about the energy costs of synthetic hydrocarbons. We're talking about something in the range of 5x the amount of energy you need. Think 5x the number of wind turbines and solar panels, and then reconsider if you still imagine that is a cheap solution.

This could make millions of older cars cleaner, also in the developing world. LPG is already cleaner, would benefit the developing world, and ICE engines can be produced without needing exotic materials, can be recycled 100% by smelting, are a proven, well known, durable technology, unlike lithium batteries (which are also proven, but recycling and exotic materials are problematic), and are and will be a popular technology in the developing world for a long time.

Also it would allow for cheaper and cleaner cars in the developed world, where not everybody can afford the electric dream many here are living.

It would also be somewhat suitable for long haul and heavy machinery, but most likely in a hybrid drivertrain setup.

Also it would solve the big issue of the German home heating and industry: how to stove away the sun and wind from the summer to the winter, when in the windless dark days nowadays coal is burnt, as battery of hydro storage cannot be scaled beyond a few days capacity at extremes.

There is already built, or cheap technology to gas powered solutions, no need to transition to new technology hastily. This would give runway to the green transition, as it could be net zero carbon footprint solution with less disturbance to the existing solutions.

Like it or not, internal combustion cars have many advantages, a big one being that they can run on different fuels. Converting to green LPG or (my pick) methanol will have to happen if we're serious about reducing transport emissions, because it's the only immediate non-cost-prohibitive option.

E85 does that even better, as the cost of being less dense. But it cools so much better you can run higher boost.

What about LPG?

And if we want LPG to be something we still have to deal with legislation, like in many countries you can't park in an underground garage with LPG.

For engines getting smaller: the LPG operation of petrol engines provides lower power output (and lower torque), so an uptick in LPG powered (dual fuel?) cars would probably mandate slightly different engines sensible (bigger ones), the market would surely adapt to it.

E85 would also be fine if it wouldn't be manufactured from intensively farmed monocultural agricultural products, which make it totally non-sustainable and non-renewable factoring in the sustainability problems of industrial agriculture (soil erosion, carbon depletion of soil, death of soil microbiome, groundwater depletion, etc)

The parking ban for LPG in closed garages is a real problem, I have faced it myself. Though it is justifiable, but then it would also be justified for the BEVs as there were cases already where (heat from) a battery fire compromised the structural integrity parking complexes, so it is a manageable risk probably, and probably mostly legislative.

They dump extra fuel to prevent knock. It's hard to melt cylinders.

> can't park in an underground garage with LPG

And yet people park. I haven't heard about an accident in the last 5 years. Maybe it could be managed by an extra detector?

LPG engines could be excellent generators (back ups or range extenders for cars and trucks). The emit less particulate matter and NOx.

I'm not sure why parking with LPG is a problem but parking with 10-20 gallons of gasoline is not?

In case of a leak there is a risk in case of a not-ventilated enough underground garage it is possible that the gas accumulates in the lower parts before it can be sensed/sniffed, and a mix of just 2.1% with air is already at risk of explosion if a spark is generated.

Security norms changed in the EU around 2001, the norm is the ECE/ONU 67-01 (though different countries may have implemented differently in the local Law) and LPG powered cars conforming to that standard are allowed (generally) to be parked in underground garages BUT only on the first underground floor and only if the garage is conforming to some (earlier) ventilation standards.

AFAIK cases of explosions/fires related to LPG car tanks are extremely rare (thanks also to the added safety measures mandated by ECE/ONU 67-01), whilst fires/explosions originated by domestic LPG use, while not common, are more common than what they should be (the tanks in themselves are generally safe, but the - often underground - pipings often are not).

IIRC, solar now gets to about 3$ per Mwth, so purely energy cost would be about 0.33$ per kg of propane if 100Mj of input energy per kg of propane stands for that electrolyser plus stated 13Mj for Co2 capture for 1 kg of propane. So, the cost is not negligible, but could be competetive even now, and solar is likely to get cheaper.

If it were electric it would require a 13k/220 = 60 amp connection, triple the domestic wiring standard here.

But also a bit misleading. Pumping heat into the atmosphere isn't really at the heart of climate change - adding insulation to the atmosphere is. It probably isn't great to pump heat into it either, but the mechanisms for radiative loss of that extra heat are (were) pretty good, and it would take a gigantic amount of heat (more than we've produced by burning fossil fuels) to shift the energy level in the atmosphere by much over longer time frames. However, effectively adding another blanket to the atmosphere is far more impactful. Last credible estimate I saw was the atmosphere now contains about an extra 8 peta-watts compared to pre-industrial times, and almost all of that comes from a reduction in "radiative forcing" (loss of heat to space, essentially) rather than additional heat generation.

They are not cosplaying at anything. It's just how it is.

> It's just how it is.

It's a fairly new trend, and as mentioned above, one that's probably already over. Germany has had outdoor Christmas markets for much longer than patio heaters have existed.

And yes, the christmas market version of being outside is obviously much older, but in my experience (also, Heidelberg in 1986) was less sitting around and more moving around outside (or in heated tents).

It's the heat that is retained that is the problem.

Still: better grid connection or home batteries are much less complicated to install than a whole new CO2 conversion set-up, plus we are going to need those if people are going to drive electric cars. The cost (energy or money) of capturing CO2 in the atmosphere into concentrate for that catalytic process.

[0] https://www.theguardian.com/environment/2008/dec/31/cement-c...

Give it time, we're working on it...

So a range of 0.018% to 0.4% over the last 500 million years. We’re currently at ~420ppm, and human impact is estimated to have been about +140ppm since the 1700s where we had been at 280ppm for the ~10,000 years prior.

If the planet ever hit 0.4% again it would be due to natural not anthropogenic reasons.

"Must", no. But hundreds millions of cars and trucks on the road right now can be converted to propane. It's relatively easy and well understood and you keep your same motor and drivetrain.

Converting existing cars and trucks to electric is so intensive it's almost unthinkable ... cost, energy input, waste, etc.

If the cost of this technology could be brought down within a decade, it would be a way of reducing emissions for the large chunk of the fleet that isn't electric, in a cost effective manner.

The other, more pragmatic, answer is that internal combustion engines aren't going anywhere. They have too many advantages over their competitors to ever fully go away, so we need cost effective ways of running them that are also carbon neutral or negative. Some of the links in this chain, like low cost electrolysis, are vital for other reasons (e.g. the food we grow uses fertilizer made from hydrogen split from fossil fuels. We need the fertilizer or the planet starves, and we need a source of hydrogen that doesn't also produce 11 tonnes of CO2 for every tonne of hydrogen produced).

The problem ultimately is that CO₂ capture from the air is another expense that has to be paid, both in terms of cost and energy. Sure, if the entire process becomes so cheap and widely available that this no longer becomes issue, then we can certainly do it. But until then, it is a major stumbling block.

The other problem is that if all you want is something more "practical" than hydrogen, you will stop at methane. Same basic idea as this, but you only need the Sabatier process. And we already have many facilities capable of dealing with methane. So we do not necessarily need to go further. But if you insist on long carbon chains, why stop at C3? Keep going until you reach C8, or even C12-20, at which point you have the equivalent of gasoline or diesel. Basically, get to the point where you have a liquid at room temperature, and it will be even more practical than propane.

That is, of course, very true. Per calculations upthread, the energy cost of DAC isn't that huge, but indeed it's for the time being a very immature technology that hasn't been demonstrated at scale.

> The other problem is that if all you want is something more "practical" than hydrogen, you will stop at methane. Same basic idea as this, but you only need the Sabatier process. And we already have many facilities capable of dealing with methane. So we do not necessarily need to go further.

In principle yes. I guess it's a question of cost. Is the cost of an H2 electrolyzer + the Sabatier reactors etc. lower than this propane electrylyzer? If this propane electrylyzer thing could be done cheaply, that could be the gamechanger. Not the fact that it's technically possible to manufacture synthetic hydrocarbons, we have multiple ways of doing that, though all of them tend to be both expensive in terms of capital cost and somewhat inefficient.

> But if you insist on long carbon chains, why stop at C3? Keep going until you reach C8, or even C12-20, at which point you have the equivalent of gasoline or diesel. Basically, get to the point where you have a liquid at room temperature, and it will be even more practical than propane.

Indeed, from a handling and transportation point of view, the longer hydrocarbons are pretty much optimal. But like above, it's a question of cost. Fischer-Tropsch installations tend to be very capital intensive, yield is an issue etc.

So if this propane electrolyzer turns out to be industrially feasible at a low enough cost, maybe it's overall more efficient to deal with pressurized storage systems.

All I’ve seen so far are speculations based on a small prototype in Iceland that is still very expensive and has access to free energy. I’ve had to add up the costs that you list myself (you are not giving any numbers), and it ends up being a prohibitively expensive gallon of fuel—an order of magnitude more expensive than it is now. How is that reasonable when most states would lose their head with a 10% increase?

My concern is that most of the time, the math goes: “Let’s assume electricity is free, and people somehow still want to drive an ICE.” and conclude with, “We just have to continue subsidizing a pathologically dangerous pollution by 90%.” hoping to capitalize on the heads of states fear of a revolution.

I can see why that looks tempting to people who refuse to admit that we must shift away from fossil fuels and latch on to plans to paint their industrial assets as renewable. Still, it ends up being an inefficient Rube-Goldberg machine, where adding solar panels on the roof of wherever you need energy works. I’m all for failing convincingly, but you must admit when it’s not working.

I’ve heard that mining equipment was too large and could never be electrified… Those converted the fastest (custom engines, high torque, regenerative power, far away from fuel supply but sunny/windy location) and with glee (lower maintenance when technicians have to fly in by helicopter). Prototype boats and airplanes can work “indefinitely” because solar panels can generate enough energy for them to work 24/7.

I’ve yet to hear about a single industrial process that needs carbon-chain fuel to work.

[1] https://news.stanford.edu/2019/10/17/new-catalyst-helps-turn...

Ruthenium and Iridium are known stable catalysts that are also among the most rare elements. Their structure used Ru. This new paper seems to propose only abundant materials. If it can be used at scale and proves to be stable that would be an important advancement.

If yes, the consequences for energy storage might be significant. The energy density of propane is 49.6 MJ/kg. Apparently, Li-Ion batteries are about 0.8 MJ/kg, more than 50x the difference.

AFAIK both fuel cells like that, and the inverse carbon capture machines, are technically possible for decades now. The issue is high cost due to precious metals in the catalyst.

Apparently, these guys have solved the issue with much cheaper stuff for the catalyst, molybdenum phosphide.

Months. I have a residential sized propane tank for gas and backup power that only gets refilled once a year at most. Worst case scenario I can go off grid for two to three months in the summer on a generator (tested frequently) and this is a pretty standard size for exurban houses in California.

Could you elaborate on that? I imagine most people do not have any concept of that. Are you talking basketball, person, tiny car, SUV, or something else in terms of size? I'm imagining something between tiny car and SUV.

If they could do the reverse (water+propane to CO2+hydrogen+electricity) at the efficiency claimed (91%), they can replace all gas turbine generators (who typically have efficiencies of only 60% at best)

500 stacked 0.5mm layers of this would make 400 volts for an ev battery or stationary AC generator. It would have a power density of 6.3 kilowatts per litre, far exceeding both lithium batteries and gas turbines.

Tesla is known to colocate them for exactly the reasons you say - also to shift load to cheaper hours of the day and to get paid by the grid for balancing services.

Orleans MA and Hyannis MA supercharger stations. The one in Hyannis is right next to the superchargers, the other is 2 minutes walk away.

I believe one or both have "bloom energy" branding.

I can't find a good picture on the internet.

by comparison, this discovery could make it a green-vs-brown fuel debate, at which point it would be much more valuable to invest in for vehicles

If you want to use that fuel, just burn it.

You'd use the plant mainly to make propane, just run it backwards when electricity prices were the highest.

So are you saying the reaction is

10 H2 + 3 CO2 <=> C3H8 + 6 H2O

Of course, neither this nor the reaction mentioned in the parent comment matches up with the diagram in the linked article which says "water + CO2 => propane + water", which well, doesn't make sense..

I’m asking because a lot of the demand for hydrocarbon that I see mentioned is for processes that have more efficient, non-hydrocarbon equivalents.

Hilariously enough even at this rate of adoption few underground garages allow entry for such vehicles.

I suppose it won't see adoption in cars anytime soon because looking at electricity prices it can't hope to be less expensive than fossil fuels.

https://terraformindustries.com/

I asked the cofounder of his thoughts here:

https://twitter.com/ccorcos/status/1694021803654693342

https://www.prometheusfuels.com/news/dude-wheres-my-fuel

I am curious how do they compare

How hard/expensive are all their materials to produce at scale?

Molybdenum is not as rare and expensive as platinum, so that’s certainly a win.

After you've re-expended the entire 20th century's worth of fossil fuels energy equivalent in sucking CO2 out of the atmosphere, not burned it, and stored it in a country-sized propane tank, then maybe we're back to 19th-century temperatures.

I apologize if this wasn't clear. It's an expression about energy potentials, and as such it's not just useful in a lab, it's an essential piece of information about the substance.

For example in the original context of this comment thread, a person asked whether there was a danger of people exhausting our atmospheric CO2 because they got too greedy with this technology - a question that can in fact not be answered meaningfully without talking about energy deltas. The fact that CO2 cannot be practically processed in a way that releases energy is the only pertinent information when talking about this.

Plants make sugar from CO2, and also burn that sugar back to CO2 (plants respire overnight - they're not pure CO2 consumption machines).

- This process produces hydrocarbon fuel. It will be burned and the carbon will return to the atmosphere.

I suppose propane could become a chemical feedstock. Then the carbon could theoretically be tied up for a while.

Pulling enough CO2 to make a kilogram of propane and then burning that kilogram of propane for electricity is still better than burning a kilogram of freshly fracked propane.

One offsets consumption. One just adds consumption.

Pretty much the only reason to do this would be because you're specifically interested in generating propane. For example, it could be very useful for ISRU on other planets, or to generate propane "for free" from a solar setup.

If your goal is energy production, you'd just use the output of solar panels directly without this costly step in the middle. If you want to store energy locally, electrolyzing water into H and O would be hugely more cost effective. But propane is a more dense fuel that would be useful for mobile applications such as ships and cars, and can also be used as a raw material in chemical synthesis.

In fact, our most effective ways to take carbon out of the atmosphere today all involve a step of letting some mineral turn into one of this carbon-rich ones, and extracting it from there.

It would cut out the cost of mining, and possibly a lot of transportation costs, if you can use the products nearby.

More CO2 should also stimulate plant growth, CO2 is a bit of a limiting factor there.

8CO2+24H2O+24e→3C3H8+16O2.

Moles of CO2=1000×1000/44.01≈22726moles.

Total moles of electrons= 24/8×22726≈68178moles.

Total charge=68178×96485≈6.58×10^9C.

E=Q×V=6.58×10^9×0.8≈5.27×10^9J.

E_actual=5.27×10^9/0.91≈5.79×10^9J.

E_actual=5.79×10^9/3.6×10^6≈1608kWh.

----------------------------------

Moles of propane= 3/8×22726≈8522moles.

Mass of propane=8522×44.1≈375,670g≈376kg.

Total energy content=376×50.35≈18,932MJ.

Usable energy= 10,791/3.6≈2,997kWh.

I’m guessing the major error is that the -0.8V is “versus reversible hydrogen electrode ”, so it’s a half-reaction and you need to fill in the correct other half reaction, and there is probably H2 involved. Then you would dig out some free energy values to see how efficient it is.

(I only read the abstract.)

Fixed the math using chat gpt :P.

Reaction: 3CO2 + 12H2 -> C3H8 + 6O2

Number of moles of electrons (n): n = 3 * 4 = 12

Total charge (Q) in Coulombs: Q = (-395 * 1 * 100 * 3600 * 0.91 / 1000) * 12 * 96485

Voltage (V): V = -0.8

Total energy for given current density: E = Q * V

Moles of CO2 in 1 ton: n_CO2 = (1000 * 1000) / 44.01

Total charge for 1 ton of CO2: Q_total = (12 / 3) * n_CO2 * 96485

Adjusted charge considering Faradaic efficiency: Q_adjusted = Q_total * 0.91

Total energy for 1 ton of CO2: E_total = Q_adjusted * V

Convert to kWh: E_kWh = E_total * 2.778e-7 E_kWh ≈ 17707.4 kWh

Gives a specific CO2 emission for propane of 13.8 kg carbon / kWh fuel, so your numbers are at least vaguely credible. But your reaction is devoid of CO2, so talking about tons of CO2 is still odd.

6 O on the left, 12 on the right.

24 H on the left, 8 on the right.

I think there is a lot more value in burning propane for heating houses. Especially in places (like Europe where I live) that are already build to use gas for heating.

Especially if you consider the massive gas-storage facilities that are common here. We have 12 billion cubic meters of gas-storage here in the Netherlands, on a yearly consumption of 40 billion. That means we could use 'green propane' to load-shift about 30% of our heating from winter to summer. That would be amazing.

Heating use is indeed very obvious, and so is transportation use. Many countries have an elaborate distribution network for LPG and fitting a car to run on LPG is also very easy.

BTW, hot air balloons also run on propane.

Mostly stored underground, but it's also shipped and stored in a liquefied state at -162C. Propane is one of the components of natural gas, so I would think any facility that is able to store natural gas should be able to store propane easily.

It must take at least as much energy to turn carbon dioxide into propane as you generate when you burn that propane to generate carbon dioxide.

In theory, yes, but you need to take into account all the energy that goes into the process, which includes the catalyst, and also the actual capture of the CO2.

The way i read it, this is "just" a way of turning already captured CO2 into fuel again in an efficient way.

Still, it does seem a little bit too good that you can obtain 3 kWh of energy by spending 1.6 kWh, but i guess time will tell.

Burning propane produces CO2 AND water. I think the missing bit is the energy required to split the water into hydrogen and oxygen before the hydrogen is used as an input to produce the propane.

Using a traditional resistive heater, you're roughly creating 1 kWh of heat by spending 1 kWh of electricity (there is some loss), but with a heat pump you're moving heat, which is also why heat pumps become much less efficient the colder the temperature as there is less heat to move, and many residential heat pumps include a regular resistive heating element as a backup.

There's a great explanatory video on how heat pumps work here : https://www.youtube.com/watch?v=7J52mDjZzto&pp=ygUgdGVjaG5vb...

Fundamentally different process from exothermal chemical reaction, or electric heating using resistive wire.

The cost of carbon capture straight from the air is about 10GJ per Tonne (they quote 8.8 and 14 from competing sources). Which is about 2800 kWh That would put a serious damper on the efficiency, but might make it viable even when 'easy' sources of CO2 (like the exhaust of fossil power plants) are no longer available.

Propane also needs to be compressed from what I can see to about 200psi. Not a huge amount but it would take special equipment and power to run a pump.

Batteries would AFAIK need a 2-4X power/weight density improvement to do anything more than short haul electric flight. Short haul electric planes are possible today but not beyond a few hundred miles range.

Or could we possibly fit an exhaust-gas tank onto our engines that holds all the combustion products, and is collected and recycled at the gas station?

It would be cool if, long term, the CO2 released by burning this in home furnaces for heating can mostly be re-captured.

Not easy enough apparently, the US gov started subsidizing/taxcutting this because there was demand for CO2 in enhanced oil recovery but the price was too high.

Only now you've thrown away some of the energy in losses doing the CO2 to propane conversion.

This would lower the efficiency of a fossil fuel powerplant, and this increase the CO2 emitted overall.

It'll cost energy, but it is a cheap source of CO2 for this electrolysis.

So again, it wouldn't work because as you note: the electric power available is less than the gas.