Sustainable Aviation Fuels (SAFs)

Detailed overview of innovation with sample startups and prominent university research


What it is

Sustainable aviation fuels (SAFs) are renewable or waste-derived fuels that offer a lower-carbon alternative to conventional jet fuel. These fuels are designed to be “drop-in” replacements, meaning they can be used in existing aircraft engines with minimal or no modifications, making them a practical solution for decarbonizing the current fleet.

Impact on climate action

Sustainable Aviation Fuels (SAFs) significantly reduce aviation’s carbon footprint by utilizing renewable sources like waste oils and agricultural residues. These fuels offer a viable alternative to traditional jet fuels, curbing emissions and fostering the transition towards a low-carbon aviation industry, crucial for combating climate change and achieving environmental sustainability.

Underlying
Technology

  • Bio-Based Feedstocks: SAFs can be produced from various sustainable feedstocks, including non-edible plants, agricultural residues, used cooking oil, and algae.
  • Power-to-Liquid (PtL) Technology: This process utilizes renewable electricity to produce synthetic fuels, such as hydrogen or synthetic kerosene, from water and captured carbon dioxide.
  • Hydrotreated Esters and Fatty Acids (HEFA): This process converts oils and fats from sustainable sources into bio-based jet fuel.
  • Fischer-Tropsch (FT) Synthesis: This method converts synthesis gas (syngas), derived from biomass or other carbon sources, into liquid hydrocarbons, including jet fuel.
  • Alcohol-to-Jet (AtJ) Technology: This process converts ethanol, produced from sustainable sources like sugarcane or corn, into jet fuel.

TRL : 7-9


Prominent Innovation themes

  • Advanced Feedstock Development: Research focuses on identifying and developing new sustainable feedstocks for SAF production, with an emphasis on non-competing land use and high biomass yields.
  • Efficient Conversion Technologies: Developing more efficient and cost-effective conversion processes to produce SAFs, lowering production costs and making them more competitive with conventional jet fuel.
  • Waste-to-Fuel Pathways: Exploring innovative ways to produce SAFs from various waste streams, such as municipal solid waste, plastics, and industrial byproducts, promoting circular economy principles.
  • Carbon Capture and Utilization (CCU): Integrating CCU technologies into SAF production processes to capture and utilize CO2, further reducing the carbon footprint of these fuels.
  • Sustainable Supply Chains: Building transparent and sustainable supply chains for SAF feedstocks and production, ensuring responsible sourcing and minimizing environmental impacts throughout the lifecycle.

Other Innovation Subthemes

  • Renewable Feedstock Exploration
  • Power-to-Liquid Fuel Synthesis
  • Hydrotreated Esters and Fatty Acids (HEFA) Process Optimization
  • Fischer-Tropsch (FT) Synthesis Advancements
  • Alcohol-to-Jet (AtJ) Technology Innovation
  • Advanced Feedstock Research and Development
  • Conversion Process Efficiency Enhancement
  • Waste-to-Fuel Transformation Techniques
  • Carbon Capture and Utilization Integration
  • High-Yield Biomass Cultivation Methods
  • Cost-Effective SAF Production Technologies
  • Municipal Solid Waste Conversion
  • Plastic Waste Utilization in SAFs
  • Industrial Byproduct Valorization

Sample Global Startups and Companies

  • LanzaJet:
    • Technology Focus: LanzaJet specializes in producing SAFs using innovative technologies such as Alcohol-to-Jet (ATJ) processes and proprietary catalysts. Their approach involves converting sustainable feedstocks like agricultural and forestry residues into low-carbon aviation fuels.
    • Uniqueness: LanzaJet stands out for its focus on commercializing advanced SAF production technologies, offering a pathway to significantly reduce the carbon footprint of aviation. Their technology enhancements enable them to produce SAFs that meet rigorous aviation industry standards.
    • End-User Segments: Their target segments include commercial airlines, private aviation companies, and military aviation, all seeking to reduce their carbon emissions and comply with increasingly stringent environmental regulations.
  • World Energy:
    • Technology Focus: World Energy is a leading producer of SAFs, utilizing a variety of sustainable feedstocks such as waste oils, fats, and greases. They employ advanced refining processes to convert these feedstocks into high-quality aviation fuels.
    • Uniqueness: World Energy distinguishes itself by operating one of the largest SAF production facilities in the world and offering a diverse portfolio of SAF products. They are known for their commitment to sustainability and for supplying SAFs that meet strict quality and performance requirements.
    • End-User Segments: Their SAFs cater to a wide range of aviation stakeholders, including commercial airlines, corporate flight departments, and government agencies, all seeking to reduce their carbon footprint and enhance their environmental stewardship.
  • Neste:
    • Technology Focus: Neste is a pioneer in renewable fuels, including SAFs, produced through their proprietary NEXBTL technology. They utilize renewable feedstocks such as vegetable oils and waste fats to produce high-quality, drop-in aviation fuels.
    • Uniqueness: Neste is renowned for its extensive expertise in renewable refining and its commitment to sustainability. Their SAFs offer a direct replacement for conventional jet fuels, with significant reductions in greenhouse gas emissions.
    • End-User Segments: Neste’s SAFs are sought after by airlines, airports, and aircraft operators globally, attracted by the prospect of reducing their carbon footprint without compromising on performance or reliability.

Sample Research At Top-Tier Universities

  • Massachusetts Institute of Technology (MIT):
    • Technology Enhancements: MIT researchers are spearheading advancements in the production and utilization of sustainable aviation fuels (SAFs). They are focusing on developing novel biochemical and thermochemical processes to convert renewable feedstocks such as biomass, algae, and waste oils into high-quality aviation fuels.
    • Uniqueness of Research: MIT’s approach involves integrating advanced catalytic and separation technologies to improve the efficiency and cost-effectiveness of SAF production. They are also exploring innovative methods for carbon capture and utilization to reduce the carbon footprint of aviation fuels.
    • End-use Applications: The SAFs developed at MIT have the potential to significantly reduce greenhouse gas emissions from the aviation sector. These fuels can be seamlessly integrated into existing aircraft engines and infrastructure, offering a viable pathway towards decarbonizing air travel.
  • University of California, Berkeley:
    • Technology Enhancements: Researchers at UC Berkeley are focusing on developing sustainable aviation fuels (SAFs) using novel biotechnological and synthetic biology approaches. They are engineering microorganisms and enzymatic pathways to efficiently convert renewable feedstocks such as agricultural residues and carbon dioxide into drop-in aviation fuels.
    • Uniqueness of Research: UC Berkeley’s research is characterized by its interdisciplinary nature, combining expertise in microbiology, molecular biology, and chemical engineering. They are exploring innovative strategies for improving the yield and scalability of SAF production while minimizing environmental impact.
    • End-use Applications: The SAFs developed at UC Berkeley have the potential to revolutionize the aviation industry by offering a sustainable alternative to conventional fossil fuels. These fuels can help airlines meet their emissions reduction targets and regulatory requirements while ensuring reliable and affordable air transportation.
  • Imperial College London:
    • Technology Enhancements: Researchers at Imperial College London are pioneering advancements in the synthesis and utilization of sustainable aviation fuels (SAFs). They are developing advanced catalytic processes and reactor designs to produce drop-in biofuels from renewable feedstocks such as biomass, waste oils, and hydrogen.
    • Uniqueness of Research: Imperial College’s research focuses on the techno-economic analysis and life cycle assessment of SAF production pathways. They are evaluating the environmental and economic feasibility of different fuel synthesis routes and identifying strategies for improving overall process efficiency and sustainability.
    • End-use Applications: The SAFs developed at Imperial College have the potential to play a crucial role in mitigating climate change and reducing the environmental impact of air travel. These fuels can help airlines achieve carbon neutrality and enhance the long-term sustainability of the aviation sector.

commercial_img Commercial Implementation

SAFs are already being commercially implemented, with a growing number of airlines using them to reduce their emissions. While current SAF production volumes are relatively small compared to conventional jet fuel demand, the industry is rapidly scaling up production capacity. Several airports have started offering SAF blending facilities, and airlines are making commitments to increase their SAF usage in the coming years.