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Berkeley Lab-led team explores a way to
create biofuels, minus the
photosynthesis
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Is there a new path to biofuels
hiding in a handful of dirt? Lawrence Berkeley National Laboratory (Berkeley
Lab) biologist Steve Singer leads a group that wants to find out. They're
exploring whether a common soil bacterium can be engineered to produce liquid
transportation fuels much more efficiently than the ways in which advanced
biofuels are made today.
The scientists are working with a
bacterium called Ralstonia eutropha. It naturally uses hydrogen as an
energy source to convert CO2 into various organic compounds.
The group hopes to capitalize on
the bacteria's capabilities and tweak it to produce advanced biofuels that are
drop-in replacements for diesel and jet fuel. The process would be powered only
by hydrogen and electricity from renewable sources such as solar or wind.
The goal is a biofuel-or
electrofuel, as this new approach is called-that doesn't require
photosynthesis.
Why is this important? Most
methods used to produce advanced biofuels, such as from biomass and algae, rely
on photosynthesis. But it turns out that photosynthesis isn't very efficient
when it comes to making biofuel. Energy is lost as photons from the sun are
converted to stored chemical energy in a plant, which is then converted to a
fuel.
"We're after a more direct way,"
says Singer, who holds appointments with Berkeley Lab's Earth Sciences Division
and with the Joint BioEnergy Institute (JBEI), a multi-institutional partnership
led by Berkeley Lab.
"We want to bypass photosynthesis
by using a microbe that uses hydrogen and electricity to convert CO2
into a fuel," he adds.
Widespread use of electrofuels
would also reduce demands for land, water, and fertilizer that are traditionally
required to produce biofuels.
Berkeley Lab's $3.4 million
electrofuel project was funded in 2010 by DOE's Advanced Research Projects
Agency-Energy (ARPA-E) program, which focuses on "high risk, high payoff
concepts-technologies promising genuine transformation in the ways we generate,
store and utilize energy."
That pretty much describes
electrofuels. ARPA-E estimates the technology has the potential to be ten times
more efficient than current biofuel production methods. But electrofuels are
currently confined to lab-scale tests. A lot of obstacles must be overcome
before you'll see it at the pump.
Fortunately, research is
underway. The Berkeley Lab project is one of thirteen electrofuel projects
sponsored by ARPA-E. And earlier this year, ARPA-E issued a request for
information focused on the commercialization of the technology.
Singer's group includes
scientists from Virginia-based Logos Technologies and the University of
California at Berkeley. The project's co-principal investigators are Harry
Beller, Swapnil Chhabra, and Nathan Hillson, who are also with Berkeley Lab and
JBEI; Chris Chang, a UC Berkeley chemist and a faculty scientist with Berkeley
Lab's Chemical Sciences Division; and Dan MacEachran of Logos Technologies.
The scientists chose to work with
R. eutropha because the bacterium is well understood and it's already
used industrially to make bioplastics.
They're creating engineered
strains of the bacterium at JBEI, all aimed at improving its ability to produce
hydrocarbons. This work involves re-routing metabolic pathways in the bacteria.
It also involves adding pathways from other microorganisms, such as a pathway
engineered in Escherichia coli to produce medium-chain methyl ketones,
which are naturally occurring compounds that have cetane numbers similar to
those of typical diesel fuel.
The group is also pursuing two
parallel paths to further boost production.
In the first approach, Logos
Technologies is developing a two-liter bioelectrochemical reactor, which is a
conventional fermentation vessel fitted with electrodes. The vessel starts with
a mixture of bacteria, CO2, and water. Electricity splits the water
into oxygen and hydrogen. The bacteria then use energy from the hydrogen to
wrest carbon from CO2 and convert it to hydrocarbons, which migrate
to the water's surface. The scientists hope to skim the first batch of biofuel
from the bioreactor in about one year.
In the second approach, the
scientists want to transform the bacteria into self-reliant, biofuel-making
machines. With help from Chris Chang, they're developing ways to tether
electrocatalysts to the bacteria's surface. These catalysts use electricity to
generate hydrogen in the presence of water.
The idea is to give the bacteria
the ability to produce much of their own energy source. If the approach works,
the only ingredients the bacteria will need to produce biofuel would be
CO2, electricity, and water.
The scientists are now developing
ways to attach these catalysts to electrodes and to the surface of the
bacteria.
"We're at the proof-of-principle
stage in many ways with this research, but the concept has a lot of potential,
so we're eager to see where we can take this," says Singer.
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# # #
Lawrence Berkeley National Laboratory addresses the world's most
urgent scientific challenges by advancing sustainable energy, protecting
human health, creating new materials, and revealing the origin and fate of
the universe. Founded in 1931, Berkeley Lab's scientific expertise has
been recognized with 13 Nobel prizes. The University of California
manages Berkeley Lab for the U.S. Department of Energy's Office of Science.
For more, visit www.lbl.gov. |
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