[Since a lot of people can't read the article and the format is annoying enough that even archive services haven't captured it, here's the text.]
As you know, Prometheus converts renewable electricity from solar and wind power into zero net carbon gasoline, diesel, and jet e-fuels (short for “electro-fuels”) that compete with fossil fuels on price. What some readers may not know is that the process we use to do this is new, is only recently possible, and is unlike anything that anyone else is doing to make synthetic fuels today. It is because of this new process that we are the only company making e-fuels that can compete with fossil fuels without new laws or subsidies — our fuels can compete simply by being better and costing less than the fossil fuels they will replace. This is a truly exciting breakthrough in our ability to solve some of the world’s most intractable problems, like climate change, energy security, and the need for increased energy-driven prosperity. But as often happens with breakthroughs of this magnitude, our process has provoked some dramatic responses - It sounds too good to be true! — and raised a lot of questions: How is it possible that your e-fuels are so much cheaper than everyone else’s? And if you can make these fuels, then where are they? Why aren’t they for sale yet? I’m here to answer these questions.
What’s everybody else doing?
If we ignore biofuels and waste-to-fuels and just focus on fuels made partially or fully from electricity from renewable sources, then everyone else who’s making e-fuels is using high temperature, high pressure synthesis. It’s been possible for almost a hundred years to make synthetic fuels from H2 and CO2 by using the Fischer Tropsch process, (invented in 1925), or similar processes that use high temperature and pressure with a catalyst to combine carbon and hydrogen into fuels. Currently, there are many companies using Fischer Tropsch or related processes that call their products e-fuels, which technically can be true if they only use electricity for CO2 capture and desorption, hydrogen generation, CO2 to CO conversion, synthesis reactions, and downstream cracking and distillation. In practice, it’s common to use fossil methane for the heat needed in these processes and to try to justify the additional CO2 this emits by promising to capture it also. Regardless of how closely they keep to the electricity-only ideal, however, none of these approaches can compete with fossil fuels on price.
What’s new about our process and why do our e-fuels cost so much less that they can compete with fossil fuels?
- Electricity is really cheap now
The first reason our fuels have such a low cost is not specific to us — it’s the recent abundance of really cheap renewable power. E-fuels are stored renewable energy. The day has long been anticipated when the cost of renewable electricity would become low enough to enable e-fuels, and that day has come. Specifically, it arrived in 2018, when the cost of utility scale solar power dropped to $0.02/kWh for the first time in a purchase by the city of Los Angeles. This marks a drop of over 90% in just ten years. The most recent record for the lowest utility scale solar bid was achieved last year at $0.01/kWh. The dramatic drop in costs is due to massive investment in solar panel manufacturing and in learning-by-doing cost reductions from making lots of solar panels. Low cost electrons mean low cost e-fuels.
The second reason our fuels are low cost, and one that is specific to us, is that we don’t need pure CO2. In order to make hydrocarbon e-fuels at scale one needs to capture CO2 from the air by direct air capture (DAC). For everyone else making e-fuels, this is a large cost. This is because their processes all require pure, pressurized CO2 gas. One obtains CO2 from the air by adsorbing the CO2 into or onto something, typically an amine liquid or amine functionalized bead, or in a hydroxide solution in water, or something more exotic, like an ionic liquid. This part isn’t so hard, and doesn’t require much energy, just a fan to blow air. In some cases, passive wind is used, but in either case, it’s not the main energy consumer.
The main energy cost is in getting the CO2 to release from the absorbent — to desorb. And that’s when things get really expensive, because this requires a lot of energy, almost always in the form of heat from burning fossil methane or a portion of the fuel produced. This is why most DAC CO2 processes cost $500-$600/ton of CO2 with a far distant and hopeful target of $100/ton at scale. But even at $100/ton CO2, any fuel one goes on to make is already too expensive to compete with fossil fuel.
At Prometheus, we don’t make or need pure CO2 gas, so we don’t need to desorb it. Therefore, we avoid the vast majority of this cost. Instead, we capture CO2 in water and then use it in water to make fuel. ARPA-E refers to this as “reactive CO2 capture” and identifies it as a significantly lower-cost DAC approach. Because our DAC tech is fundamentally different, our cost to capture CO2 is only $36/ton, the lowest in the world, and the only one low enough to enable fuel that competes on price with fossil. (More on this below.)
- We use electrocatalysts, not catalysts that need high pressure and temperature
The third reason our fuels are low cost, and another reason that is specific to us, is that we use electrocatalysts to do what only pressure and temperature could do before. The first widely read paper on this showed that CO2 in water could be turned into ethanol at a faradic efficiency of 63%. This means that 63% of the electrons that went into products in the process went into ethanol. We licensed a second-generation of this catalyst that has even better performance, making much larger and more complex carbon-based fuels with electricity alone.
Using electrocatalysts instead of the high pressure and temperature catalysts everyone else uses gives us a big reduction in cost because we can do the same job at room temperature and pressure while using much less expensive materials. It’s also great for our system performance because we can turn our process on and off quickly, matching intermittent solar and wind power. High pressure and temperature systems can’t operate like that.
- We’re the only ones who don’t need distillation
The fourth reason our fuels are low cost is that we’re the only company in the world that can replace distillation with nanotechnology to separate fuels from the water in which they’re made. In my previous startup, Mattershift, I commercialized a carbon nanotube (CNT) membrane, and published on it in 2018. Numerous academic publications have shown that membranes like this could separate alcohols from water, but until Mattershift produced them, no commercial CNT membranes were available. Previously, the only way to separate alcohols from water was to use distillation, another highly inefficient and expensive heat-based separation process. The CNT membranes solve this problem, using over 90% less energy than distillation and dramatically lowering the cost of extracting our fuel. This is a big deal because it reduces what is a major cost for other e-fuel makers to a minor cost for us.
Ok, that sounds good, but how does all this compete with fossil oil and gas?
The math on the cost of our e-fuel is pretty simple. The only inputs are air (CO2 and water) and electricity, and the only outputs are oxygen and fuel. The cost of the inputs plus the cost of the equipment and its maintenance make up nearly all of the cost. There are some other operating costs, like the vacuum pump and coolers on the CNT membranes or the power for pumps and controls, but these are less than 1% of total operating costs. I won’t include taxes or delivery fees since these vary a lot from place to place.
The main cost is electricity. The energy density of liquid e-fuels is very high, the main reason that they have long been desired as a solution for decarbonizing long-haul shipping and aviation. For gasoline, the energy density is approx. 33 kWh/gallon. In a TEA study we did last year with a third-party engineering firm, the estimate for the overall efficiency of our process (chemical energy in the fuel / electrical energy used to make it) is approx. 43%. This is a really great efficiency, because it includes everything involved from start to finish, including DAC of CO2, synthesis of the fuel, and separating the fuel so it’s ready to use. At this efficiency, our gasoline will need approx. 77 kWh of electricity per gallon. If the cost of power is $0.02/kWh, then the electricity cost of our e-gasoline is $1.54/gallon.
The next cost is CO2. The third-party TEA put our DAC cost at $36/ton of CO2 at $0.02/kWh, making it the lowest cost DAC in the world, and this cost drops further with lower costs of electricity. A gallon of gasoline contains approx. 8.9 kg of CO2 per gallon, so at a cost of $36/ton, this results in a CO2 cost for us of $0.32/gallon.
The most important cost after electricity is equipment cost, typically called capital cost. Adding up the electricity and CO2 costs, we get $1.86/gallon. If we want to stay below $3.00/gallon (for example), then we need to keep the capital and maintenance costs less than $1.14/gallon. Our cost models tell us that we can have capital and maintenance costs that are significantly lower than that, due to the advantages listed above, including not needing CO2 desorption or fuel distillation equipment, using low cost materials due to low temperatures and pressures, and deploying mass manufacturing methods like those used to make cars.
Ok, that’s cheap fuel, I’m into it. But where are the demos? If you can do this, why can’t I buy the fuel yet? . . . Dude, where’s my fuel?
In short, the fuel is coming. We’re about to do more and bigger demos. And we can replace fossil fuels a lot faster than most people think. Here’s where we’re at now.
First, we make fuel from the air all the time at Prometheus. We’ve been doing it since we started with the Fuel Forge Demo 1 system I built in the Y-Combinator batch in 2019. We just don’t make that much at any given time, and there’s a really good reason for this. We’re optimizing the most expensive part of the system, the electrochemical stack (which we call the Faraday Reactor), and the fastest and best way to do that is one commercial-scale cell (a cathode, anode, and separator) at a time. The thing is one cell doesn’t make that much fuel. What it does do is make enough to tell us what to do to iterate to the next cell design, which is exactly what we need to be doing to improve our performance and costs as quickly and inexpensively as possible. If we stopped this process to replicate one of the iterations of the cell to many cells, we could make more fuel, but we wouldn’t learn any more, we’d use up a lot of time and materials, and it wouldn’t prove that we can compete with fossil fuels on cost - the thing that matters.
It’s worth pointing out that companies that do demos to show they can make e-fuel aren’t showing that much. After all, it’s been possible to make fuel that way for over 100 years. What matters is showing that you can make it at low cost, and that is something you do with chemical analysis, bills of materials, and cost models. Kind of boring as demos go, but it’s what matters most. We’ve been killing these demos, which is why we are the first unicorn in the e-fuels space.
So let’s talk about capital cost, the one we need to keep below $1.14/gallon to stay below $3.00/gallon fuel.
For this it helps to compare our Titan Fuel Forges to a more familiar system, a hydrogen electrolyzer. Our Fuel Forges are similar in many ways to hydrogen electrolyzers, in that they consist of many layers of cells, each consisting of a cathode, an anode, and a separator. In an H2 Electrolyzer, the anode is where electrons are stripped from water, producing oxygen, and the cathode is where electrons are added to protons, producing hydrogen gas. In our system, the anode works the same way, but our cathode, in addition to making H2, also makes liquid fuels. Both systems have capital costs dominated by the costs of the electrochemical stacks.
This brings us to the issue of economies of scale. For high temperature / high pressure systems like Fischer Tropsch or e-methanol to gasoline (MTG), economies of scale mean large refinery installations that cost billions of dollars and years to build (and still don’t get to cost-competitive fuels). For modular, mobile systems like our Titan Fuel Forges, however, economies of scale mean mass manufacturing. Building a Fuel Forge isn’t like building a refinery, it’s like building a car. When you mass manufacture a product, the cost of the product asymptotically approaches the cost of the materials. Since our process uses only inexpensive metals like copper and steel, inexpensive gasket materials and other low pressure, low temperature components, our cost of materials is low. This is a very powerful approach for low fuel cost.
One thing that’s especially advantageous about the stack dominating the cost of the system is that bringing economies of scale to stack manufacturing by making many cells is very nearly as powerful as making many Fuel Forges overall. For manufacturing methods like injection molding, for example, one can get to very low costs very quickly, delivering impressive economies of scale. A Faraday Reactor, like an H2 electrolyzer stack, is made of many layers, so making even a few Fuel Forges can quickly lead to low stack costs.
For this reason, driving down the cost of the Faraday Reactor is the single most effective way to drive down the cost of a Titan Fuel Forge, and therefore the capital cost component of the fuel.
In the stage we’re at now, we’re close to locking down the design of our commercial-scale cell and stack design and are about to start automating their assembly into many-cell stacks. Even with the slow global supply chain we’ve all been dealing with lately, this can happen pretty quickly, because it’s a fairly simple assembly process — just slow when it’s being done by hand. This means we’ll be making larger quantities of fuel and we’ll get to do the demos with motorcycles, race cars and classic cars, and jetpacks and planes that we know you want to see. Up to this point, I haven’t been willing to do these larger-scale demos because of the significant slow-down they would involve, delaying our progress towards launching commercial fuel - the thing we care about most. But the right time to do them is coming soon. Personally, I’m really looking forward to doing those demos, because I like putting on a good show.
Our not-so-secret plan is to get the Faraday Reactors into automated assembly and take all the data we’ve gathered to design and build the first Titan Fuel Forge 1.0 commercial system. I think we can start the build this year, but I’ve learned that schedules are hard to predict right now. If everything goes our way, we’ll be shipping fuel very soon.
After that, we’ll be making more Forges with automated Faraday Reactor assembly and most of the rest by hand as fast as we can, but to really scale quickly, we’ll need to build a factory to make many fuel forges. We call this factory the MetaForge.
The rate at which we can build Fuel Forges in the first MetaForge will be set by the rate at which new solar and wind power can be built. If we assume for the moment that each Titan Fuel Forge will have a rating of 1 MW each, then 1,000 Fuel Forges will require 1 GW of new renewable power to operate. If 250 GW of new renewable power for “power to X” projects are built each year, then the MetaForge could make 250,000 fuel forges per year. (Compare this rate of production to that of car factories that can make more than 500,000 cars per year). At this rate, these forges could decarbonize approx. 30 million cars per year. This is a very rapid decarbonization rate compared to any other options currently under consideration. Alongside the growth of battery electric vehicles, it’s feasible using this approach to decarbonize the global vehicle fleet entirely by 2040. Using e-fuels to replace all energy products made from oil and gas across sectors could eliminate over 20 GT of CO2 emissions per year.
I don't think I've ever seen a web site where the content was so interesting, but the presentation was so piss poor that the bulk of visitors likely leave without having even read any of this cool stuff.
For the love of god, throw your web site away and start again with some simple, static HTML pages.
I'd second this, just tried loading it on a tablet and gave up on the load screen. It was 50/50 I'd read the comments but I'm glad I did now.
Please please, for goodness sake, put a quick loading static page front and center quick! This stuff is too important and too cool to be lost to same hokey web design.
The page we are reading can quite easily be remade into a normal web page as it involves few of the exotic/mind blowing animations seen elsewhere on the website.
The first page view shouldn't be loading all that crap that isn't being used.
Thank you for copy and pasting this. They need to fire their designer right away. There is absolutely no reason for me to wait 10+ seconds for their website to load text data. WTAF are they thinking?
It may seem like a small thing, but it is an important detail, and it makes me question if the company is snake oil or not. It doesn't appear very professional to take this approach. Maybe it was ok in 1998, but not today.
Yeah I gave up and came here to read the complaints against the site and I'm glad I did as I found the article interesting.
Even more "interesting" is that in their news section was this article: https://www.prometheusfuels.com/news/prometheus-site-of-the-... - so I don't think they're going to be listening to HN about their design anytime soon, which is a shame as that site is awful.
The irony that you made me sit through the loading animation to see that.
I've never heard of the FWA, but I'm going to make my own award site and give myself awards every year, maybe biannually.
Oh dear. I had to visit it just to see my self and it looks like it preloads the whole site? Alot of pictures even though the article shows none. 356MB in total for just some text.
When you move around the site it has a lot of very nice, stylized 3d and cool transition effects. It's weird that it preloads nearly everything on first visit.
I wonder the extent to which Trevor Milton’s shenanigans at Nikola Motors have made life more difficult for other entrepreneurs in this space.
“Our tech works in the lab. Simple math shows it can be competitive in the market. Now, we’re focusing on scaling the tech.” Those words make sense when coming from a genuine effort that could succeed. Those words are therefore copied by charlatans as well.
I have no reason to think Prometheus is in the latter camp, but the presence of that camp makes life harder for them I think.
As you know, Prometheus converts renewable electricity from solar and wind power into zero net carbon gasoline, diesel, and jet e-fuels (short for “electro-fuels”) that compete with fossil fuels on price. What some readers may not know is that the process we use to do this is new, is only recently possible, and is unlike anything that anyone else is doing to make synthetic fuels today. It is because of this new process that we are the only company making e-fuels that can compete with fossil fuels without new laws or subsidies — our fuels can compete simply by being better and costing less than the fossil fuels they will replace. This is a truly exciting breakthrough in our ability to solve some of the world’s most intractable problems, like climate change, energy security, and the need for increased energy-driven prosperity. But as often happens with breakthroughs of this magnitude, our process has provoked some dramatic responses - It sounds too good to be true! — and raised a lot of questions: How is it possible that your e-fuels are so much cheaper than everyone else’s? And if you can make these fuels, then where are they? Why aren’t they for sale yet? I’m here to answer these questions.
What’s everybody else doing?
If we ignore biofuels and waste-to-fuels and just focus on fuels made partially or fully from electricity from renewable sources, then everyone else who’s making e-fuels is using high temperature, high pressure synthesis. It’s been possible for almost a hundred years to make synthetic fuels from H2 and CO2 by using the Fischer Tropsch process, (invented in 1925), or similar processes that use high temperature and pressure with a catalyst to combine carbon and hydrogen into fuels. Currently, there are many companies using Fischer Tropsch or related processes that call their products e-fuels, which technically can be true if they only use electricity for CO2 capture and desorption, hydrogen generation, CO2 to CO conversion, synthesis reactions, and downstream cracking and distillation. In practice, it’s common to use fossil methane for the heat needed in these processes and to try to justify the additional CO2 this emits by promising to capture it also. Regardless of how closely they keep to the electricity-only ideal, however, none of these approaches can compete with fossil fuels on price.
What’s new about our process and why do our e-fuels cost so much less that they can compete with fossil fuels?
- Electricity is really cheap now
The first reason our fuels have such a low cost is not specific to us — it’s the recent abundance of really cheap renewable power. E-fuels are stored renewable energy. The day has long been anticipated when the cost of renewable electricity would become low enough to enable e-fuels, and that day has come. Specifically, it arrived in 2018, when the cost of utility scale solar power dropped to $0.02/kWh for the first time in a purchase by the city of Los Angeles. This marks a drop of over 90% in just ten years. The most recent record for the lowest utility scale solar bid was achieved last year at $0.01/kWh. The dramatic drop in costs is due to massive investment in solar panel manufacturing and in learning-by-doing cost reductions from making lots of solar panels. Low cost electrons mean low cost e-fuels.
[chart: https://storage.googleapis.com/prometheus-fuels.appspot.com/...]
- We don’t need pure CO2
The second reason our fuels are low cost, and one that is specific to us, is that we don’t need pure CO2. In order to make hydrocarbon e-fuels at scale one needs to capture CO2 from the air by direct air capture (DAC). For everyone else making e-fuels, this is a large cost. This is because their processes all require pure, pressurized CO2 gas. One obtains CO2 from the air by adsorbing the CO2 into or onto something, typically an amine liquid or amine functionalized bead, or in a hydroxide solution in water, or something more exotic, like an ionic liquid. This part isn’t so hard, and doesn’t require much energy, just a fan to blow air. In some cases, passive wind is used, but in either case, it’s not the main energy consumer.
The main energy cost is in getting the CO2 to release from the absorbent — to desorb. And that’s when things get really expensive, because this requires a lot of energy, almost always in the form of heat from burning fossil methane or a portion of the fuel produced. This is why most DAC CO2 processes cost $500-$600/ton of CO2 with a far distant and hopeful target of $100/ton at scale. But even at $100/ton CO2, any fuel one goes on to make is already too expensive to compete with fossil fuel.
At Prometheus, we don’t make or need pure CO2 gas, so we don’t need to desorb it. Therefore, we avoid the vast majority of this cost. Instead, we capture CO2 in water and then use it in water to make fuel. ARPA-E refers to this as “reactive CO2 capture” and identifies it as a significantly lower-cost DAC approach. Because our DAC tech is fundamentally different, our cost to capture CO2 is only $36/ton, the lowest in the world, and the only one low enough to enable fuel that competes on price with fossil. (More on this below.)
- We use electrocatalysts, not catalysts that need high pressure and temperature
The third reason our fuels are low cost, and another reason that is specific to us, is that we use electrocatalysts to do what only pressure and temperature could do before. The first widely read paper on this showed that CO2 in water could be turned into ethanol at a faradic efficiency of 63%. This means that 63% of the electrons that went into products in the process went into ethanol. We licensed a second-generation of this catalyst that has even better performance, making much larger and more complex carbon-based fuels with electricity alone.
Using electrocatalysts instead of the high pressure and temperature catalysts everyone else uses gives us a big reduction in cost because we can do the same job at room temperature and pressure while using much less expensive materials. It’s also great for our system performance because we can turn our process on and off quickly, matching intermittent solar and wind power. High pressure and temperature systems can’t operate like that.
- We’re the only ones who don’t need distillation
The fourth reason our fuels are low cost is that we’re the only company in the world that can replace distillation with nanotechnology to separate fuels from the water in which they’re made. In my previous startup, Mattershift, I commercialized a carbon nanotube (CNT) membrane, and published on it in 2018. Numerous academic publications have shown that membranes like this could separate alcohols from water, but until Mattershift produced them, no commercial CNT membranes were available. Previously, the only way to separate alcohols from water was to use distillation, another highly inefficient and expensive heat-based separation process. The CNT membranes solve this problem, using over 90% less energy than distillation and dramatically lowering the cost of extracting our fuel. This is a big deal because it reduces what is a major cost for other e-fuel makers to a minor cost for us.
Ok, that sounds good, but how does all this compete with fossil oil and gas?
The math on the cost of our e-fuel is pretty simple. The only inputs are air (CO2 and water) and electricity, and the only outputs are oxygen and fuel. The cost of the inputs plus the cost of the equipment and its maintenance make up nearly all of the cost. There are some other operating costs, like the vacuum pump and coolers on the CNT membranes or the power for pumps and controls, but these are less than 1% of total operating costs. I won’t include taxes or delivery fees since these vary a lot from place to place.
The main cost is electricity. The energy density of liquid e-fuels is very high, the main reason that they have long been desired as a solution for decarbonizing long-haul shipping and aviation. For gasoline, the energy density is approx. 33 kWh/gallon. In a TEA study we did last year with a third-party engineering firm, the estimate for the overall efficiency of our process (chemical energy in the fuel / electrical energy used to make it) is approx. 43%. This is a really great efficiency, because it includes everything involved from start to finish, including DAC of CO2, synthesis of the fuel, and separating the fuel so it’s ready to use. At this efficiency, our gasoline will need approx. 77 kWh of electricity per gallon. If the cost of power is $0.02/kWh, then the electricity cost of our e-gasoline is $1.54/gallon.
The next cost is CO2. The third-party TEA put our DAC cost at $36/ton of CO2 at $0.02/kWh, making it the lowest cost DAC in the world, and this cost drops further with lower costs of electricity. A gallon of gasoline contains approx. 8.9 kg of CO2 per gallon, so at a cost of $36/ton, this results in a CO2 cost for us of $0.32/gallon.
The most important cost after electricity is equipment cost, typically called capital cost. Adding up the electricity and CO2 costs, we get $1.86/gallon. If we want to stay below $3.00/gallon (for example), then we need to keep the capital and maintenance costs less than $1.14/gallon. Our cost models tell us that we can have capital and maintenance costs that are significantly lower than that, due to the advantages listed above, including not needing CO2 desorption or fuel distillation equipment, using low cost materials due to low temperatures and pressures, and deploying mass manufacturing methods like those used to make cars.
Ok, that’s cheap fuel, I’m into it. But where are the demos? If you can do this, why can’t I buy the fuel yet? . . . Dude, where’s my fuel?
In short, the fuel is coming. We’re about to do more and bigger demos. And we can replace fossil fuels a lot faster than most people think. Here’s where we’re at now.
First, we make fuel from the air all the time at Prometheus. We’ve been doing it since we started with the Fuel Forge Demo 1 system I built in the Y-Combinator batch in 2019. We just don’t make that much at any given time, and there’s a really good reason for this. We’re optimizing the most expensive part of the system, the electrochemical stack (which we call the Faraday Reactor), and the fastest and best way to do that is one commercial-scale cell (a cathode, anode, and separator) at a time. The thing is one cell doesn’t make that much fuel. What it does do is make enough to tell us what to do to iterate to the next cell design, which is exactly what we need to be doing to improve our performance and costs as quickly and inexpensively as possible. If we stopped this process to replicate one of the iterations of the cell to many cells, we could make more fuel, but we wouldn’t learn any more, we’d use up a lot of time and materials, and it wouldn’t prove that we can compete with fossil fuels on cost - the thing that matters.
It’s worth pointing out that companies that do demos to show they can make e-fuel aren’t showing that much. After all, it’s been possible to make fuel that way for over 100 years. What matters is showing that you can make it at low cost, and that is something you do with chemical analysis, bills of materials, and cost models. Kind of boring as demos go, but it’s what matters most. We’ve been killing these demos, which is why we are the first unicorn in the e-fuels space.
So let’s talk about capital cost, the one we need to keep below $1.14/gallon to stay below $3.00/gallon fuel.
For this it helps to compare our Titan Fuel Forges to a more familiar system, a hydrogen electrolyzer. Our Fuel Forges are similar in many ways to hydrogen electrolyzers, in that they consist of many layers of cells, each consisting of a cathode, an anode, and a separator. In an H2 Electrolyzer, the anode is where electrons are stripped from water, producing oxygen, and the cathode is where electrons are added to protons, producing hydrogen gas. In our system, the anode works the same way, but our cathode, in addition to making H2, also makes liquid fuels. Both systems have capital costs dominated by the costs of the electrochemical stacks.
This brings us to the issue of economies of scale. For high temperature / high pressure systems like Fischer Tropsch or e-methanol to gasoline (MTG), economies of scale mean large refinery installations that cost billions of dollars and years to build (and still don’t get to cost-competitive fuels). For modular, mobile systems like our Titan Fuel Forges, however, economies of scale mean mass manufacturing. Building a Fuel Forge isn’t like building a refinery, it’s like building a car. When you mass manufacture a product, the cost of the product asymptotically approaches the cost of the materials. Since our process uses only inexpensive metals like copper and steel, inexpensive gasket materials and other low pressure, low temperature components, our cost of materials is low. This is a very powerful approach for low fuel cost.
One thing that’s especially advantageous about the stack dominating the cost of the system is that bringing economies of scale to stack manufacturing by making many cells is very nearly as powerful as making many Fuel Forges overall. For manufacturing methods like injection molding, for example, one can get to very low costs very quickly, delivering impressive economies of scale. A Faraday Reactor, like an H2 electrolyzer stack, is made of many layers, so making even a few Fuel Forges can quickly lead to low stack costs.
[chart: https://storage.googleapis.com/prometheus-fuels.appspot.com/...]
https://inspirationfeed.com/how-to-correctly-calculate-the-c...
For this reason, driving down the cost of the Faraday Reactor is the single most effective way to drive down the cost of a Titan Fuel Forge, and therefore the capital cost component of the fuel.
In the stage we’re at now, we’re close to locking down the design of our commercial-scale cell and stack design and are about to start automating their assembly into many-cell stacks. Even with the slow global supply chain we’ve all been dealing with lately, this can happen pretty quickly, because it’s a fairly simple assembly process — just slow when it’s being done by hand. This means we’ll be making larger quantities of fuel and we’ll get to do the demos with motorcycles, race cars and classic cars, and jetpacks and planes that we know you want to see. Up to this point, I haven’t been willing to do these larger-scale demos because of the significant slow-down they would involve, delaying our progress towards launching commercial fuel - the thing we care about most. But the right time to do them is coming soon. Personally, I’m really looking forward to doing those demos, because I like putting on a good show.
Our not-so-secret plan is to get the Faraday Reactors into automated assembly and take all the data we’ve gathered to design and build the first Titan Fuel Forge 1.0 commercial system. I think we can start the build this year, but I’ve learned that schedules are hard to predict right now. If everything goes our way, we’ll be shipping fuel very soon.
After that, we’ll be making more Forges with automated Faraday Reactor assembly and most of the rest by hand as fast as we can, but to really scale quickly, we’ll need to build a factory to make many fuel forges. We call this factory the MetaForge.
The rate at which we can build Fuel Forges in the first MetaForge will be set by the rate at which new solar and wind power can be built. If we assume for the moment that each Titan Fuel Forge will have a rating of 1 MW each, then 1,000 Fuel Forges will require 1 GW of new renewable power to operate. If 250 GW of new renewable power for “power to X” projects are built each year, then the MetaForge could make 250,000 fuel forges per year. (Compare this rate of production to that of car factories that can make more than 500,000 cars per year). At this rate, these forges could decarbonize approx. 30 million cars per year. This is a very rapid decarbonization rate compared to any other options currently under consideration. Alongside the growth of battery electric vehicles, it’s feasible using this approach to decarbonize the global vehicle fleet entirely by 2040. Using e-fuels to replace all energy products made from oil and gas across sectors could eliminate over 20 GT of CO2 emissions per year.