Inspired by nature, scientists explore pathways
to clean, renewable solar fuel.
CHICAGO, IL - Scientists at the U.S. Department of
Energy’s (DOE) Brookhaven National Laboratory are trying to design
catalysts inspired by photosynthesis, the natural process by which
green plants convert sunlight, water, and carbon dioxide into oxygen
and carbohydrates. The goal is to design a bio-inspired system that
can produce fuels like methanol, methane, and hydrogen directly from
water and carbon dioxide using renewable solar energy. Four Brookhaven
chemists discussed their research on this so-called "artificial
photosynthesis" at the 233rd National Meeting of the American Chemical
Society.
Mother Nature’s work isn’t so easy to perform in a
laboratory. In the beginning stages of photosynthesis, the absorption
of light by chlorophyll – a molecule responsible for the green color
in plants – drives the complex photosynthetic reaction. The energy of
sunlight is transferred in the form of electrons and positive charges
throughout a pathway of various steps before the final products –
carbohydrates (the plants’ food) and oxygen – are produced. However,
because the components of natural photosystems do not work properly
outside their normal environment, the Brookhaven scientists are
investigating other cataylsts that could be used to replicate these
natural functions. Below are summaries of these talks, which are part
of the American Chemical Society symposium "Catalysis Relevant to
Energy and Sustainability."
Catalyzing Oxygen Production from Water
To replicate one of the important steps in natural
photosynthesis, Brookhaven chemists James Muckerman and Dmitry
Polyansky have turned to molecular complexes containing metals such as
ruthenium that can drive the conversion of water into oxygen, protons,
and electrons. These ruthenium catalysts hold water molecules in place
to make oxygen bonds while the protons and electrons are transferred
among the molecules and the catalyst, providing the charges necessary
to continue the photosynthesis process. During this multi-step
reaction, Polyansky tries to experimentally determine the stability
and geometry of the molecules with different kinds of time-resolved
optical spectroscopy techniques. Muckerman compares the lab results to
calculations based on theory. Because the intermediate species can be
very unstable, they might exist for much less than a millisecond, or
one thousandth of a second. This makes catching the molecules in
action very difficult. "The catalysts we’re using are not necessarily
the ultimate catalysts to be used in any practical photosynthetic
device," Muckerman said. "The aim of our work is to understand how
theses catalysts work and to elucidate the detailed mechanistic steps
so we can design better catalysts."
Building a Bio-inspired Catalytic Cycle for Fuel
Production
Further down the photosynthetic line, there’s
another molecule whose function scientists are trying to replicate.
Like a robotic arm on an assembly line, a special molecule called the
NADP+/NADPH coenzyme cycles back and forth, picking up a proton and
two electrons and depositing them (or their combined negative ion,
called a hydride) for use in the eventual production of carbohydrates.
This coenzyme molecule is recyclable in natural photosynthesis, but
cannot perform its catalytic function in the laboratory. The goal for
scientists is to find an NADPH-inspired catalyst that will mimic
nature’s cyclical motion. "Using visible light, we want to regenerate
hydride donors, where the same molecule will just keep turning over,"
said Brookhaven chemist Etsuko Fujita. Like Muckerman and Polyansky,
Fujita and her coworkers are also using a ruthenium-based complex for
their functional model. This artificial complex has been shown to work
similarly to NADP+/NADPH, acting as the source of two electrons and a
proton in the transformation of acetone to isopropanol. The
researchers are investigating how the hydride donors can be generated
using light, and plan to use this type of artificial catalyst for the
production of fuels from carbon dioxide (or related molecules) in the
future.
Finding a "Supercritical" Solution to CO2
Reduction
One of the final steps in "artificial
photosynthesis" is turning carbon dioxide molecules (CO2)
into clean, useful fuels. Catalysts capable of converting CO2
into carbon monoxide (CO) - a powerful source of fuel – already exist.
However, "the problem is that the catalysts are inefficient and slow –
nowhere near efficient enough to use in a practical application," said
Brookhaven chemist David Grills. One of the reasons for this is that
the liquid solvent used to dissolve the chemicals deactivates one of
the key intermediate species that reacts with CO2. So
Grills is trying to eliminate the need for this solvent by
pressurizing and heating up the CO2 (which is a gas under
normal conditions) until it takes on some of the properties of a
liquid and can act as a good solvent. "Now, our solvent is the
reactant and nothing else is getting in the way," Grills said. In
addition to speeding up the reaction time, the physical properties of
this so-called supercritical CO2 can be easily tuned to
change the reaction, and the use of toxic organic solvents is avoided.
Source / Further
information:
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Publishing date: 28-Mar-2007
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The Brookhaven research is funded through the
DOE’s Chemical Science Program (Photochemistry and Radiation
Research) and Hydrogen Program, which implements the President’s
Hydrogen Fuel Initiative, a five-year program that began in 2003
to sponsor research, development, and demonstration of hydrogen
and fuel cell technologies. Specifically, the funding derived from
DOE’s Office of Basic Energy Sciences. Collaborators include
scientists at the University of Houston, the Institute for
Molecular Science in Japan, and the University of Nottingham in
the United Kingdom.
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One of ten national laboratories overseen and
primarily funded by the Office of Science of the U.S. Department
of Energy (DOE),
Brookhaven National Laboratory conducts research in the
physical, biomedical, and environmental sciences, as well as in
energy technologies and national security. Brookhaven Lab also
builds and operates major scientific facilities available to
university, industry and government researchers. Brookhaven is
operated and managed for DOE's Office of Science by Brookhaven
Science Associates, a limited-liability company founded by the
Research Foundation of State University of New York on behalf of
Stony Brook University, the largest academic user of Laboratory
facilities, and Battelle, a nonprofit, applied science and
technology organization.
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