Opening a new window on the way plants generate the oxygen we breathe, researchers used an X-ray laser at the Department of Energy's (DOE) SLAC National Accelerator
"All
life that depends on oxygen is dependent on photosynthesis," said Junko
Yano, a Lawrence Berkeley National Laboratory chemist and co-leader in the
experiment. "If you can learn to do this as nature does it, you can apply
the design principles to artificial systems, such as the creation of renewable
energy sources. This is opening up the way to really learn a lot about changes
going on in the catalytic cycle."
Catalysts
are vital to many industrial processes, such as the production of fuels, food,
pharmaceuticals and fertilizers, and represent a $12 billion-per-year market in
the United States alone. Natural catalysts are also key to the chemistry of
life; a major goal of X-ray science is to learn how they function in
photosynthesis, which produces energy and oxygen from sunlight and water.
The
LCLS experiment focused on Photosystem II, a protein complex in plants, algae
and some microbes that carries out the oxygen-producing stage of
photosynthesis. This four-step process takes place in a simple catalyst -- a
cluster of calcium and manganese atoms. In each step, Photosystem II absorbs a
photon of sunlight and releases a proton and an electron, which provide the
energy to link two water molecules, break them apart and release an oxygen
molecule.
Past
studies were able to freeze crystals of the catalyst at various stages of the
process and see how it looked. But scientists wanted to see the chemistry take
place. This was not possible at other X-ray facilities, because the fragile
crystals had to be frozen to protect them from radiation damage.
However,
the LCLS X-ray laser comes in such brief pulses -- measured in quadrillionths
of a second -- that they could probe the crystals at room temperature in a
chemically active state, before any damage set in, and generate data on two of
the four steps in oxygen generation.
"We
decided to use two X-ray techniques at once at the LCLS: crystallography to
look at the overall atomic structure of Photosystem II, and spectroscopy to
document the position and flow of electrons in the catalyst," said Vittal
Yachandra, a Berkeley Lab chemist and co-leader of the project. "The electrons
are important because they are involved in making and breaking bonds and other
processes at the heart of chemical reactions."
Another
co-leader, SLAC physicist Uwe Bergmann, said, "This result is a critical
step in the ultimate goal to watch the full cycle of the splitting of water
into oxygen during photosynthesis." The use of both techniques also
verified that the molecular structure of the samples is not damaged during
measurement with the LCLS, he said. "It's the first time that we have
resolved the structure of Photosystem II under conditions in which we know for
sure that the machinery that does the water splitting is fully intact."
In
future LCLS experiments, the researchers hope to study all the steps carried
out by Photosystem II in higher resolution, revealing the full transformation
of water molecules into oxygen molecules -- considered a key to unlocking the
system's potential use in making alternative fuels.
"Getting
a few of the critical snapshots of this transition would be the final goal,"
said Jan Kern, a chemist who holds a joint position at Berkeley Lab and SLAC
and is the first author of the paper. "It would really answer all of the
questions we have at the moment about how this mechanism works."
Besides
scientists from Berkeley Lab, SLAC and Stanford University, researchers from
Technical University Berlin in Germany, Umea and Stockholm universities in
Sweden and the European Synchrotron Radiation Facility in France also
participated in the research. This work was supported by the DOE's Office of
Science, the National Institutes of Health, the German Research Foundation
(DFG), the Alexander von Humbolt Foundation, Umea University, the Knut and
Alice Wallengberg Foundation and the Swedish Energy Agency
0 comments:
Post a Comment