Power to liquid
How do you convert renewable energy into a liquid fuel? Power to liquid is a type of sustainable aviation feel that is synthetic.
SAF is produced using the fisher tropsch process. The FT process has been around for a century. Established a century ago. Approved by ASTM.
A key challenge on the horizon, however, is binding targets from ReFuelEU Aviation to produce more SAF from more challenging feedstocks, such as biomass residues, and using renewable power and carbon dioxide (CO₂).
eSAF is made using PTL technology.
The feed stocks are in virtually endless supply as they are renewable energy, solar energy wind energy co2 and water.
(In particular, synthetic SAF (also called eSAF or RFNBO-SAF), made using power-to-liquids (PTL) technology, has high potential because the feedstocks (solar and wind energy, CO₂ and water) are in virtually endless supply. )
Combining production of synthetic SAF and bio-SAF can be an enabler for early projects.
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PtL is that it can be transported and distributed via the existing network of fossil-fuel infrastructure, including pipelines and filling stations.
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Subtitle; Established…. 100 years
Subtitle; Approved …. By ASTM, The American Society of testing materials established over a century ago.
PtL is an alternative fuel that is JetA/JetA1-approved
Subtitle; Existing. .. infrastructure
Technology ready
Process plant
Subtitle; Reliable…Readily available feed stock.
Subtitle; same energy density. ? How does energy density of kerosene compare to energy density of shell XX?
Subtitle: carbon reduction
Subtitle or box - drivers for decarbonation are both customer preferences and regulation, including the « refuel aviation eu regulations.
Readily available feed stock
Feed stock availability for production of eSAF Is virtually limitless. This is because the feed stock is renewable energy.
XTL is X to liquid where X is a range of feedstocks from renewable sources.
Where X stands for Power, renewable energy provides the feedstock, powering hydrogen production from water. Importantly, the hydrogen produced this way is green hydrogen extracted by splitting water with electricity . This is environmentally superior. Direct air capture carbon dioxide is the carbon source.
Where X stands for biomass, the biomass is the Feed stock carbon source
Where X stand for waste, then waste is the carbon source.
- Renewable energy powers electrolysers to produce green hydrogen.
- Climate-neutral CO₂ – captured via, for example, Direct Air Carbon Capture – is converted into carbon feedstock.
- Carbon feedstocks are synthesised with green hydrogen – via processes such as Fischer-Tropsch – to generate liquid hydrocarbons. They are then converted to produce a synthetic equivalent to kerosene.
XTL pathways include biomass-to-liquids
(BTL), power-to-liquids (PTL), and waste-to-
liquids (WTL).
Security of Supply - Energy subtitle or box
Having a range of energy sources for the power to wind or solar for example when it’s windy, you can make energy from wind power and when it’s sunny you can make energy from solar power so that you always have that back up that reliability security of energy supply.
Security of Supply - feedstock subtitle or box title
Having a range of feed docs for the carbon source with Xtl the carbon source can be biomass to liquid, power to liquid or waste to liquid.
The date by which they change to sustainable aviation fuel needs to be made is not very far away and the planes that are currently flying will still be flying. So the compatibility of the fuel needs to be a direct swap it needs to have the same energy density as kerosene. But it needs to have a much lower carbon mission.
Not enough feed stock from cooking oil or animal fats
Shell Xtl is the integrated process across the whole value chain to make safe from the feed dock and through the technologies required. This increases reliability of supply as it streamlined the handoffs between the different processes and parts of the value chain.
However, while SAF is an integral part of aviation decarbonisation, most of the current supply is from a pathway known as HEFA (hydrotreated esters and fatty acids), which includes waste oils and fat, but quantities of these feedstocks are limited. As such, achieving the industry’s low-carbon goals will require a mix of different pathways to produce SAF, including the growth of eSAF.
So, what exactly is eSAF and why is it creating a buzz?
In a nutshell, eSAF, like all SAF pathways, is compatible with jet engines and offers a similar performance to fossil fuels. eSAF is a synthetic fuel derived from renewable energy.
eSAF, like all SAF pathways, is compatible with jet engines and offers a similar performance to fossil fuels. eSAF is a synthetic fuel derived from renewable energy.
Renewable electricity generated from hydro, solar or wind power is the low-carbon energy of the future. However, we already know that electric-powered flight will only be possible for short-haul journeys in the foreseeable future due to the weight of the batteries required. For larger aircraft and long-haul flights electricity needs to be converted into a synthetic fuel.
One option is to convert electricity into hydrogen, which can then be used as an aviation fuel. The problem here is that hydrogen has an energy-density-per-unit volume that is one quarter of traditional jet fuel1, so a redesign of much of the aircraft from the propulsion system to fuel storage is necessary, as are changes to airport and refuelling infrastructure.
This is where eSAF derived from power-to-liquid (PtL) technology comes in. Renewable electricity (from sources such as solar, hydro or wind) is used to break water into its components of hydrogen and oxygen via an electrolysis process. Carbon dioxide captured from the air, or from biogenic or industrial sources, together with this hydrogen are then converted to carbon monoxide and water through the reverse water gas shift process. Using Fischer-Tropsch (FT) synthesis technology, more hydrogen and carbon monoxide is converted into a wax – a sort of synthetic crude oil that can be upgraded to different fuels, including eSAF. Legislation currently allows us to use FT technology to blend eSAF up to 50% with conventional jet fuel (although in the future it is hoped 100% synthetic fuels will be approved and available) and it can be used as a drop-in fuel. It can be easily stored, transported and distributed using existing infrastructure.
The carbon neutrality of eSAF originates from the fact that the fuel only emits when burnt as much carbon as was input into the production process from direct carbon capture or existing emissions from other industrial sectors. Electricity from renewable sources is used in the production.
Essentially, it comes down to cost. To be commercially viable and competitive with conventional jet fuel, eSAF needs to be produced at low cost. At the moment eSAF is still in the development stage and is considerably more expensive to produce and purchase - it can currently be eight times the cost of conventional jet fuel and two to three times the cost of SAF made from HEFA or municipal solid waste (MSW)2. These fuels are already approved by ASTM international for use in jet engines with up to a 50% blend rate with conventional jet fuel.
However, based on the significant role eSAF is expected to play in the future, investment in the development and scaling of these fuels is critical. The good news is there is already legislation in Europe that places the development of eSAF at the forefront of aviation’s sustainability agenda. Germany for example has agreed a roadmap which will come into effect in 2026 for the development and use of eSAF for the aviation sector. The European Union proposal ‘Fit for 55’ includes ambitious goals for eSAF starting in 2030 with 0.7% of jet fuel and reaching 28% in 20503.
While these mandates mean initially at least that the cost of eSAF to customers will be around eight times more expensive than fossil fuel and at least twice as expensive as alternative SAF pathways, it’s about creating demand for renewable energy and ultimately driving down the price. As such government mandates will push the industry to learn faster and move towards reducing the costs on this technology with eSAF expected to be commercialised after 2030 and more widely available post 2040.
With the price of renewable electricity for hydrogen production, alongside the high cost and logistics of rolling out electrolysers being key challenges with respect to eSAF production and cost, it’s encouraging to see that renewable energy costs have dropped 90% in the last decade. There’s still of course a long way to go. However, with these costs expected to continue decreasing and innovations in carbon sourcing – by securing carbon monoxide from existing industrial sources instead of having to process carbon dioxide from the atmosphere helping to cut energy costs by around 30% - it is feasible that eSAF could reach cost parity with other jet fuels, including other SAF pathways.
Meanwhile, further investment in the development of refineries will also help scale production and therefore drive costs down.
Although it’s not going to be easy, Air bp is committed to achieving its net-zero ambitions incorporating SAF strategies through a mix of different viable technology pathways to develop the sustainable fuels of the future. Some regions will prioritise specific pathways with a strong focus on sustainable feedstock and land use as well as low carbon hydrogen sources, resulting in the growth of eSAF and second-generation biomass (which uses agricultural and forestry residue as feedstock). Others could favour domestic supply resulting in the production of alcohol-to-jet (AtJ) from ethanol or SAF from municipal solid waste.
It’s clear that PtL technology and the development of eSAF will play an integral role in reimagining the energy of tomorrow. And with government mandates driving the development of eSAF, they are not only an area that’s ripe for development, but also ripe with potential to play an integral role in enabling decarbonised air travel.
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