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Bioenergy

Sandia provides the foundational science and technology to enable the production of renewable, low carbon-intensity fuels and bio-advantaged products from biomass. Sandia’s Biological Sciences research facilitates and safeguards the nation’s bioeconomy.

Sandia focuses on lignocellulosic, waste, and algal biomass feedstocks. Sandia’s unique capabilities encompass the areas of synthetic biology, pilot-scale algae cultivation, biomass characterization and conversion, high-throughput enzyme assays, systems analysis, lifecycle and techno-economic modeling, and computational bioscience for advanced bioproducts and biofuels production.

Sustainable Aviation Fuels

Sustainable aviation fuel (SAF) is produced using renewable or waste-derived sources and can significantly reduce the carbon footprint of the airline industry. Aviation is considered an especially challenging transportation sector to electrify, and electrification is unlikely in the near term. The SAF Grand Challenge Roadmap: Flight Plan for Sustainable Aviation Fuel from the U.S. Departments of Energy, Transportation, and Agriculture, in collaboration with the Environmental Protection Agency, articulates plans to achieve at least 50% reduction of lifecycle greenhouse gas emissions compared to conventional jet fuel and supply 100% of aviation fuel demand by 2050.

Among the six action areas of the SAF Grand Challenge Roadmap, Sandia specializes in Feedstock Innovation, Conversion Technology Innovation, and Enabling End Use.

  • Expanding the production of feedstocks with purpose-grown algae and other renewable carbon resources
  • Soil carbon sequestration modeling and experimentation
  • Enabling the conversion of abundant waste streams to intermediates, fuels, and co-products
  • Predicting fuel properties and identifying fuels
  • Discovering efficient, low carbon-intensity pathways to SAF
  • Quantifying the social and environmental benefits of using SAF beyond carbon emissions accounting
  • Optimizing blend constituents such that fuel properties meet drop-in specifications
  • Understanding how to co-develop new combustor hardware in ways that leverage the beneficial properties of synthetic fuel components (e.g., improved thermal stability)
a plane gleams in the sun at an airport
Sandia scientists along with researchers from several other agencies and labs are working on a comprehensive strategy to produce sustainable aviation fuels on a commercial scale as part of the Sustainable Aviation Fuel Grand Challenge.

Algal Fuels and Products

Strain Improvement

Algal strain improvement develops highly productive algal cultures that resist predators and environmental stressors and are suitable for cultivation in large-scale algal farming operations.

Strain improvement R&D at Sandia includes:

  • Prospecting and isolating algae strains to identify algae with desirable properties;
  • Investigating potential biological improvements via selection, modification, and genetic engineering to improve photosynthetic efficiency, growth rates, lipid productivity, biomass yield, or other desirable traits;
  • Increasing the productivity and stability of algal cultures through the modulation of the microbial ecology of the pond and engineering microbial consortia; and
  • Developing and applying tools and methods to rapidly screen strains for promising traits and productivity.
A researcher stands beside an algae raceway. They hold a white plastic instrument that is partially submerged in the algae-filled water.
Sandia researcher Yorgos Kepesidis at one of Sandia’s Algae Raceway Testbeds within the Applied Biosciences Laboratory.

Algae Production

Commercial-scale algae production could help meet the transportation fuel needs of the United States. Algal biofuels use a relatively small land area compared to lignocellulosic fuels—fuels produced from agricultural waste or energy crops. Microalgae consume CO2 as a nutrient, grow using impaired water sources (e.g., brackish water) on land that does not compete with food, and produce much higher fuel yields than other biomass feedstocks grown on land.

Sandia is focused on:

  • Production and conversion of whole-turf algae polycultures that maximize fuels, chemicals, and other nutrients
  • Real-time diagnostics and monitoring of pathogens and predators to mitigate crop losses from pond crashes
  • Developing a molecular understanding of the stress in algal culture resulting from scale-up
  • Conducting lifecycle and systems analysis of algal biorefineries
  • Removing harmful nutrients and metals from waterways and recovering them for reuse
Sungwhan Kim, a scientist at Sandia, looks over a tank with filamentous algae at Sandia’s Algae Raceway Testbeds within the Applied Biosciences Laboratory.

Waste and Biomass Conversion to Fuels and Products

Biomass from agricultural residues, forestry, biomass energy crops, and organic wastes have the potential to provide about 1 billion tons of renewable carbon resources per year that can serve as feedstocks to produce low carbon-intensity biofuels and other bioproducts. Sandia innovates in methods development and engineering to cost-effectively convert these feedstocks for hard-to-decarbonize sectors of the economy.

Sandia is focused on:

  • Advanced technologies that break down biomass and liberate sugars that can be converted to biofuels, developing a new toolbox to transform intermediates into fuels
  • Consolidated fermentation of biomass from algae and other energy crops containing proteins when unsuitable for food or feed
  • Development of platform organisms capable of consuming a wide range of biomass substrates and downstream conversion to valuable products at high titers, rates, and yields
  • Understanding and developing a wide range of biochemical, chemical, and thermochemical approaches to depolymerizing lignin, a recalcitrant component of certain biomass, to increase its value
  • Lifecycle analysis and techno-economic modeling
  • Developing computational tools for retrosynthetic analysis
Two researchers stand behind a large, flat piece of equipment with an array of upright test tubes organized across the top
Drs. HeeJin Hwang and Saptarshi Ghosh stand in front of a Labman Formulation Engine, a machine used to weigh lignocellulosic biomass.

Damian Carrieri

(925) 294-2832

djcarri@sandia.gov

Anthe George

(925) 294-2723

angeorg@sandia.gov