Plant-based jet fuel could reduce emissions by 68%

Replacing petroleum-based aviation fuel with sustainable aviation fuel derived from a type of mustard plant can reduce carbon emissions by up to 68%, according to new research from University of Georgia scientist Puneet Dwivedi.

Dwivedi led a team that estimated the break-even price and life cycle carbon emissions of sustainable aviation fuel (SAF) derived from oil obtained from Brassica carinata, a non-edible oilseed crop. The study was published in GCB Bioenergy.

“If we can secure feedstock supply and provide suitable economic incentives along the supply chain, we could potentially produce carinata-based SAF in the southern United States,” said Dwivedi, associate professor in the Warnell School of Forestry and Natural Resources.

Global warming, primarily induced by energy-related anthropogenic CO2 emissions, can be mitigated by replacing fossil-based fuels with alternative renewable energy sources.

The aviation industry emits 2.5 percent of all carbon dioxide emissions nationwide and is responsible for 3.5 percent of global warming.

With an expected five percent increase in aviation activity in this decade and up to a 20 percent increase by 2050, the carbon emissions of the sector will continue to grow if nothing is done. Therefore, the International Civil Aviation Organization (ICAO), a specialized agency of the United Nations for the aviation industry, adopted a goal of carbon-neutral growth of international aviation from 2020. In addition, the International Air Transport Association has set a goal of a 50 percent reduction in CO2 emissions by 2050.

In 2019, the United States consumed 101 billion L of conventional aviation fuel, nearly 20 percent of the global consumption. Replacing conventional aviation fuel with SAF can be an effective strategy to achieve the desired emission reduction goal in the United States. Existing literature suggests that the use of SAF derived from various feedstocks such as camelina, canola, and soybean can have 50 to 78 percent relative carbon savings compared with conventional aviation fuel

“Carinata-based SAF could help reduce the carbon footprint of the aviation sector while creating economic opportunities and improving the flow of ecosystem services across the southern region,” said Dwivedi.

Pasture of yellow flowers of Brassica carinata

Sustainable fuel tax credit

Dwivedi’s findings come at an opportune time for US companies. In September, President Joe Biden proposed a sustainable fuel tax credit as part of the Sustainable Aviation Fuel Grand Challenge, which brings federal agencies together to scale up the production of SAF nationwide. Biden set the goal of a 20 percent drop in aviation emissions by 2030 and achieving a fully zero-carbon aviation sector by 2050.

The proposed tax credit requires a 50 percent reduction in life cycle carbon emissions – a standard that carinata exceeds, according to the team’s findings.

The price for producing SAF from carinata ranged from $0.12 per litre on the low end to $1.28 per liter, based on existing economic and market incentives. The price for petroleum-based aviation fuel was $0.50 per litre – higher than carinata-based SAF when current economic incentives were included in the analysis.

“Current policy mechanisms should be continued to support manufacturing and distribution of SAF. The Grand Challenge announced by President Biden could be a game-changer in supporting carinata-based SAF production in the southern region,” Dwivedi said.

Growing carinata

Carinata, also known as Ethiopian Mustard and Abyssinian Mustard, is an oil-based feedstock such as camelina and soybean and was suggested as a new potential feedstock for SAF production. It was introduced in the south-eastern United States in 2010 through a joint research collaboration between the University of Florida Institute of Food and Agricultural Sciences (UF-IFAS) and Nuseed.

Dwivedi is part of the Southeast Partnership for Advanced Renewables from Carinata, or SPARC, a $15 million project funded by the US Department of Agriculture’s National Institute of Food and Agriculture. Through SPARC, researchers have spent the past four years investigating how to grow carinata in the southeast USA, exploring questions related to optimum genetics and best practices for the highest crop and oil yield. With those answers in place, Dwivedi is confident about carinata’s role in supporting the regional economy and environment.

About 1.4 million hectares of land were found suitable for carinata production in the USA. Researchers found that carinata could be easily integrated into the current cropping systems in US southern states, as it grows well in winter months when agricultural land remains unused and, therefore, provides much-needed cover to otherwise exposed soils and reduces soil erosion.

Unlike soybean and canola, there is no food-versus-fuel debate associated with carinata as it is not suitable for direct human consumption. Besides the carbon benefit of replacing conventional aviation fuel with carinata-based SAF, other economic benefits include the production of high-protein animal meal, propane, and naphtha as co-products and the profit share from these co-products. Growing a winter crop could provide additional income to the farmers, create local jobs, and boost the regional economy.

“In the South, we can grow carinata as a winter crop because our winters are not as severe compared to other regions of the country,” he said. “Since carinata is grown in the ‘off’ season it does not compete with other food crops, and it does not trigger food versus fuel issues. Additionally, growing carinata provides all the cover-crop benefits related to water quality, soil health, biodiversity and pollination.”

The missing piece of the puzzle, according to Dwivedi, is the lack of local infrastructure for crushing the seed and processing the oil into SAF. His current research focuses on modelling the economic and environmental feasibility of producing and consuming carinata-based SAF across Georgia, Alabama and Florida by taking a supply-chain perspective.

“Our results would be especially relevant to the state of Georgia, which is the sixth-largest consumer of conventional aviation fuel in the country, hosts the busiest airport in the world, and is home to Delta, a leading global airline company,” he said. “I am looking forward to pursuing more research for providing a sustainable alternative to our current model of air travel. Carinata has the potential to be a win-win situation for our rural areas, the aviation industry, and most importantly, climate change.”

Co-authors on the study include Asiful Alam and Md Farhad Hossain Masum, both at the University of Georgia. SPARC also includes Brian Bledsoe and Dan Geller, College of Engineering, and Henry Sintim and Greg Colson, College of Agricultural and Environmental Sciences.

Funding for this research was received through the USDA-NIFA Bioenergy Coordinated Agricultural Project Grant # 2016-11231.

This study is a part of a special issue (“Sustainable Aviation Fuel Production from Brassica carinata in the Southern United States”) published in GCB Bioenergy.

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