University Of Kentucky Researchers Lead A National Team, Transforming Solid Waste Into Aviation Fuel

JORDAN STRICKLER

LEXINGTON, KENTUCKY

In a move towards sustainable energy and waste management, the University of Kentucky has launched a pioneering research initiative that seeks to turn everyday trash into high-quality sustainable aviation fuels (SAF). 

Titled "Surface Enhanced Smart Preprocessing of Municipal Solid Wastes for Year-Round Supply of Conversion-Ready Feedstocks," the study aims to address excessive landfill waste. Led by Jian Shi, associate professor in the Martin-Gatton College of Agriculture, Food and Environment Department of Biosystems and Agricultural Engineering (BAE), this project has been awarded $2.12 million in federal funding from the Department of Energy (DOE). 

The United States currently faces a critical challenge with over 50% of municipal solid waste (MSW) ending up in landfills, leading to increased greenhouse gas emissions and resource loss. This project seeks to address these issues head-on by developing innovative technologies to enhance the surface properties and uniformity of MSW feedstocks – facilitating their efficient conversion into biofuels and bioproducts. 

The project is a collaborative effort involving a multi-institutional team, including researchers from Iowa State University, Idaho National Laboratory, Red Rock Biofuels and Wasatch Integrated Waste Management.  

Spanning 36 months, the initiative aims to: 

• Develop novel blending and densification strategies to improve the stability and convertibility of waste plastics with biomass feedstocks. 
• Implement mechanical separation methods to remove inorganic contaminants from MSW. 
• Create a rapid, nondestructive 3D imaging technology for comprehensively characterizing MSW fractions. 
• Use deep learning-based predictive models to guide preprocessing strategies and optimize feedstock quality. 

“The team wants to try and leverage advanced 3D imaging and hyperspectral technologies to identify and categorize waste materials,” Shi said. “This technological approach allows for the efficient sorting of waste components suitable for biofuel conversion, a critical step managed through machine learning algorithms. These algorithms, akin to those used by tech giants for image recognition, play a crucial role in determining waste composition and optimizing the sorting process.” 

Upon completion, the project is expected to deliver a novel preprocessing strategy tailored for converting non-recycled MSW into high-quality, conversion-ready feedstock for SAF biorefineries. This will mark a significant milestone in advancing biofuels and bioproducts research, promoting sustainable MSW-based bioeconomy and addressing the technical risks associated with the thermochemical conversion of MSW to SAF. 

By turning trash into valuable jet fuel, Shi and his team are not just addressing environmental issues but are also paving the way for a sustainable industrial model that other sectors might emulate. 

"We’re aiming to close the loop between waste generation and energy production,” said Mike Montross, BAE professor and co-principal investigator of the project. “We want not only to reduce landfill use and greenhouse gas emissions but also to enhance energy security by developing domestic, renewable energy sources."  ∆

JORDAN STRICKLER: University of Missouri