Converting waste into aviation fuel
Recent tensions surrounding the Strait of Hormuz and the resulting constraints on global oil flows have once again exposed how dependent aviation remains on a handful of fragile supply routes. When one of the world’s most critical oil chokepoints is disrupted, the consequences are immediate: rising fuel costs, supply shortages, and uncertainty across global air transport.
In this context, Sustainable Aviation Fuel (SAF) takes on a new and often overlooked role. Beyond its potential to significantly reduce carbon emissions, SAF represents a pathway to greater energy independence. Locally or regionally produced sustainable fuels could reduce reliance on volatile global oil markets—making aviation not just greener, but more resilient in the face of geopolitical disruptions
In this second part, we’ll explore the new technology of sustainable aviation fuel and provide an example of how a laboratory uses our analytical methods.
360.000+ Flights
ICAO data cited by the US Alternative Fuels Data Center shows 360,000+ commercial flights have used SAF across 46 airports (mainly US and Europe).
~ 80% reduce Lifecycle Emissions
Depending on pathway and feedstock, SAF can reduce lifecycle emissions by up to ~ 80% versus conventional jet fuel.
70% SAF usage until 2050
ReFuelEU Aviation sets minimum SAF shares of 2% (2025), 6% (2030) and 70% (2050) at EU airports.
6.6% SAF
According to data from ReFuelEU Aviation, EU airports must achieve a 6% share of sustainable aviation fuel (SAF) by 2030.
SAF represents one of the most promising paths to decarbonizing air travel.
However, aviation fuel standards are strict: oxygen content, sulfur levels and thermal stability must all fall within tight specifications. Accurate determination of elemental composition, including oxygen at very low concentrations, is therefore critical at every stage of fuel development and qualification.
One facility putting this into practice is a SAF research lab in Dublin.
Elemental analysis in action
The Sustainable Aviation Fuels (SAF) Research Facility demonstrates how advanced elemental analysis supports the development and validation of next generation fuels, many of which are derived from biomass, lignocellulosic residues, or other underutilized carbon sources. As part of a wider shift towards decarbonization and resource efficiency, these fuels offer a path to cleaner energy, and understanding their exact composition is crucial.
At this dedicated research laboratory, Elementar's CHNSO analyzer, vario EL cube, plays a central role in determining the C, H, N, S, and O content of a wide range of fuels and intermediates.
These include conventional jet fuels, SAF blends, oxygenated compounds, and solid biomass materials.
By establishing a consistent, traceable understanding of elemental composition, the team can evaluate energy content, track efficiency, and support combustion and emissions calculations, all of which are essentialfor qualifying alternative fuels under frameworks such as ASTM D4054.
Elemental analysis is important because it links the chemistry of the process inputs to the behavior of the fuels produced. For jet fuel and SAF blends, accurate carbon and hydrogen values are needed to compare different fuels, estimate energy content, and support combustion and emissions calculations. The ability to analyze liquid fuels and solid biomass using a single analyzer reduces reliance on external laboratories and shortens turnaround times.
This is particularly important when working with limited sample volumes or when rapid iteration is needed during fuel development and evaluation campaigns.
As the work at SAF research facility shows, pairing waste-processing technologies with powerful elemental analysis enables operators to ensure environmental stewardship, economic viability, and enhanced resource efficiency, turning one of society's persistent challenges into a strategic advantage.
Element's Magazin No 3
In our ELEMENT's Magazin, we cover sophisticated analytical topics and show, how CHNOS elemental analysis, stable isotope analysis (IRMS), TOC analysis, protein analysis according to Dumas and optical emission spectrometry (OES) can be used and how they influence our daily life.
Edition No. 03 on Megatrend Neo-Ecology (Decarbonization, Chemical Recycling, Waste-to-Energy)
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