Biofuel from Bacteria and Sunlight
University of Minnesota
Shewanella as an Ideal Platform for Producing Hydrocarbons
St. Paul, MN
01/01/2010 to 08/31/2012
Direct solar fuel technologies use photosynthetic microorganisms to produce liquid fuels directly from solar energy. Many photosynthetic microorganisms already produce fuels and fuel precursors, such as fatty acids and hydrocarbons. The challenge is finding cost-effective ways for the microorganisms to efficiently produce these fuels in large quantities and in forms that can be easily incorporated into the existing transportation fuel infrastructure. Meeting this challenge is critical because it would help reduce U.S. dependence on foreign oil and limit harmful emissions from traditional gasoline-powered vehicles.
Project Innovation + Advantages:
The University of Minnesota is developing clean-burning, liquid hydrocarbon fuels from bacteria. The University is finding ways to continuously harvest hydrocarbons from a type of bacteria called Shewanella by using a photosynthetic organism to constantly feed Shewanella the sugar it needs for energy and hydrocarbon production. The two organisms live and work together as a system. Using Shewanella to produce hydrocarbon fuels offers several advantages over traditional biofuel production methods. First, it eliminates many of the time-consuming and costly steps involved in growing plants and harvesting biomass. Second, hydrocarbon biofuels resemble current petroleum-based fuels and would therefore require few changes to the existing fuel refining and distribution infrastructure in the U.S.
If successful, the University of Minnesota would produce a biofuel that can easily integrate into the existing transportation fuel infrastructure.
Increasing production of domestic biofuels could help the U.S. cut foreign oil imports by 33% in 15 years.
Widespread use of biofuels could help reduce and stabilize gasoline prices for consumers.
This project could create a carbon-neutral system by recycling carbon dioxide from fuel combustion back into a fuel. It also requires none of the intensive farming practices or land associated with current biofuel crops.