Carbon Impact

Carbon reduction is achieved not only by replacing fossil fuels, but by recovering value from industrial waste at the source.

Carbon Facts

2.5%

Share of total global CO₂ emissions attributed to the aviation sector.

65%+

Minimum lifecycle greenhouse gas reduction required under RED III for a fuel to qualify as sustainable.

6,000

Ton CO₂e per year Potential annual carbon reduction per facility through avoided disposal emissions and replacement of fossil-based feedstocks.

How NAKI Reduces Carbon Emissions

Municipal solid waste landfill site with compacted trash piles

Step 1- Avoided Disposal Emissions

Industrial sludge is currently sent to landfill, incineration, or external treatment.
Each of these routes generates emissions from transport, processing, and organic degradation. On-site recovery prevents a portion of these emissions at the source.

Fatty slaughterhouse sludge collected in industrial container

Step 2- Reduced Organic Load

Lipids are energy and carbon rich components. Their removal reduces the organic load in the wastewater system and lowers the energy required for treatment.

Less energy means fewer operational emissions.

Commercial aircraft being refueled with Sustainable Aviation Fuel on airport

Step 3- Fossil Feedstock Replacement

Recovered lipids serve as renewable feedstock in HEFA pathways for the production of Sustainable Aviation Fuel (SAF) and renewable diesel.

Each ton of lipid replaces fossil-based inputs in the fuel value chain.

Carbon dioxide molecule CO2 illustration with one carbon and two oxygen atoms

Step 4- Lifecycle Emissions Reduction

Industrial sludge is currently sent to landfill, incineration, or external treatment.
Each of these routes generates emissions from transport, processing, and organic degradation. On-site recovery prevents a portion of these emissions at the source.