Unique Bioreactor Finds Algae's Sweet Spot
A unique bioreactor at the
It does so by revealing the intricate biochemical rearrangements that algae undergo when grown in different locations in
"We've almost doubled the fuel we can get out of the same amount of biomass by using these additional components," said NREL Senior Scientist
The Simulated Algal Growth Environment (SAGE) reactor resides in the
The reactor so precisely controls light, temperature, and delivery of carbon dioxide that it can mimic conditions anywhere. If scientists want to know how algae will grow in brackish water in the southwestern
"We can model how a particular strain would grow in different locations around
"Feed and Starve" Approach Yields More Potential Fuel
Algae use the chlorophyll in their cells to turn sunlight into energy through photosynthesis. Add in nutrients and carbon dioxide, and the algae can produce sugars while rapidly reproducing.
Three "champion" strains of algae grow in the NREL reactor, which allows about five times the culture volume of other similar commercially available controlled-environment reactors. With its large size and ability to recreate real-world conditions, NREL's reactor allows researchers to grow dense cultures in far less time.
Optimal conditions-nutrients, carbon dioxide, and sunlight-lead to the extra energy capable of doubling the algae's productivity.
NREL has also come up with better and faster ways to analyze and characterize the components in the algae conversion process. "We harvest every other day," yielding maximum information about the changes in an algae population that can double in size twice a day, Laurens said.
Algal cells absorb the sunlight, which, together with carbon dioxide, grows the colony. For the strains being evaluated, the more humid air and warmer nights of
Laurens and NREL Bioconversion Engineer
"Once the algae run out of nitrogen, they turn into couch potatoes," Nagle said. "The cells start eating a lot of carbon and sitting around, putting on weight. That weight is literally in the form of carbohydrates and oils"-just what the biofuels industry needs from the little critters.
The "feed and starve" rotation is one useful pathway to getting more oils out of the algae.
Industry Wants All Parts of the Algae Now
NREL is working with
"From the feedstock, we get these different products-lipids, proteins, carbohydrates," Nagle said. A few years back, industry would approach research labs with a specific request-how to use algae to get diesel oil. Now, they want it all: protein to turn into butanol or methane; lipids to turn into diesel; carbohydrates to turn into a third fuel.
From 1978 to 1996, NREL embarked on a great search and cataloging of algae. "It's fun to think it's all coming back," said Nagle. "We're now working with industry partners and other universities, collaborating and really moving this forward."
NREL's contributions include using sunlight to drive growth, and using growing cells to convert solar energy to chemical energy by converting carbon dioxide to organic molecules, along with a comprehensive analysis of the different biomass components.
"We take these champion strains and put them into virtual environments, particular locations in
NREL is analyzing how to get the most out of the harvested biomass. A pretreatment with dilute acid yields fatty acids that can be used for diesel-like biofuels and carbohydrates that can be fermented to ethanol. That still leaves proteins that can be used for other kinds of fuel. Working with
"We've been able to examine the fine variables and recommend the best tradeoffs in production of biomass, taking the biomass chemical composition into account. Like, 'this scenario won't yield as much biomass, but you would get much higher oil content,'" Laurens said. "Ultimately, it will come down to how many total gallons of biofuel we can make per acre of algal ponds per year. This is no different than our measure of corn productivity in terms of bushels per acre per year." Researchers ultimately place all the pieces together and advise on the process' economic viability through a techno-economic analysis.
In large-scale outdoor cultivation-for example, in large open ponds such as those in
Industry Is Intrigued, and
Nagle remembers the heady times in the 1980s when oil companies invested a lot of money in algae research. "It's like we put a message in a bottle and sent it out to sea," he said. "Now it's coming back, and that's pretty exciting."
After the first romance with algae, irrational exuberance ebbed, and oil companies became wiser and smarter, say Laurens and Nagle. These companies are investing dollars in algae research again, and funding from the
Companies such as
Cost is falling steadily, and "you're not going to run out of algae" as production increases, Nagle said.
NREL will remain a key player, "a good neutral third party in the game, doing our own great research but also keeping our finger on the pulse of industry," Laurens said. "It allows us to gauge who is where. And we see that that there's a lot going on, that they're starting to take this very seriously. We're seeing companies that are serious, that have significant plans for the commercialization of algae."
Learn more about NREL's biomass research (http://www.nrel.gov/biomass/).
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