- The widespread development and use of synthetic fuels is still at least a decade away and depends on the successful deployment of other technologies, but companies that position themselves now are best positioned for success according to the latest Horizons report by data and analytics company Wood Mackenzie.ย ย
The report: โAdding fire to e-fuelsโ states that e-fuels are a synthetic alternative to fossil fuels and can decarbonise difficult to electrify sectors without the need for the early scrapping of long-life equipment. This means e-fuels can offer a solution to power critical segments of transportation such as ships, long-haul aircraft and heavy-duty commercial vehicles.ย
The report states that e-fuels, which are also known as electrofuels, eFuels, synthetic fuels, Power-to-X (PtX), Power-to-Liquids (PtL) and renewable fuels of non-biological origin (RFNBOs), are produced by combining electrolytic (green) hydrogen, made by electrolysing water using renewable electricity, with captured carbon or nitrogen. An e-fuel can be considered carbon neutral if the emissions released into the atmosphere during its combustion are equal to (or less than) the captured COโ used to produce it.ย
โIdentifying pathways from legacy fuels into low-carbon alternatives is a perennial challenge for incumbent energy players,โ says Murray Douglas, Vice President of Hydrogen Research at Wood Mackenzie. โE-fuels offer companies an intriguing prospect at the intersection of electrons and molecules and the potential to capitalise on existing technical, commercial and marketing capabilities makes it an appealing, if challenging, opportunity for many.โย
Challenges abound for large-scale deploymentย
The report also states that commercial viability is the key challenge in scaling up e-fuel production with green hydrogen production and COโ capture costs both high. The subsequent conversion process to the final e-fuel product is both energy and capital intensive โ and delivery costs must also be considered.ย
โThere is no shortage of offtakers seeking low-carbon fuels, but the gap between cost of production and willingness to pay is sizeable,โ Douglas says. โEach e-fuel has an incumbent fuel it aims to displace, all of which are much cheaper and this means their success will be dictated by policy to mandate volumes, place a cost on emissions and lower production costs.โย
Douglas adds that current conversion technologies differ depending on the final e-fuel desired, but the key challenge for all of them is in integrating green hydrogen, carbon or nitrogen, and their subsequent conversion in a large-scale commercial e-fuel production facility.ย ย
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RFEUA: ReFuelEU, FEUM:FuelEU ย
Source: Wood Mackenzie Lens Hydrogen and Liquid Renewable Fuels Service; European Commissionย
Policy makers will need to wield both carrot and stickย ย
The report states that currently most e-fuel proposals aim to source COโ from a variety of feedstocks with biogenic sources with a low cost of capture, such as biogas and ethanol plants, dominating. But as the production of e-fuels grows the available molecules from such facilities will become scarcer and more dispersed. Costs will rise as e-fuel producers scour for feedstock while looking to scale.ย
This means that in the long-term global policy makers will have to set the standards for where e-fuel producers source COโ. In Europe, point-source COโ capture from fossil-fuel power generation will only be permitted until 2036 and from other fossil-fuel industries until 2041. Consequently, large volumes from net carbon dioxide removal (CDR) technologies โ direct air capture (DAC) and bioenergy with carbon capture (BECC) โ will be required.ย ย
โGlobally, governments are going to have to take a holistic approach where incentives and penalties are introduced to ensure e-fuel production will be able to ramp up to a scale that will be required,โ Douglas says.ย ย ย
The report concludes that producers who can pair low-cost renewables and biogenic COโ sources will have first mover advantage. However, putting this type of complex and technology-heavy production model in place is a lengthy process that must start now for large-scale production to be in place by the mid-2030โs.ย
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