Scientists are working to create an
“artificial leaf” that imitates a living leaf’s
chemical photosynthesis process to
convert sunlight and water into a liquid
fuel like methanol for cars and trucks.
Credit: National Aeronautics and Space
Scientists are now making progress toward development of an “artificial leaf” that mimics a real leaf’s chemical magic with photosynthesis, but instead converts sunlight and water into a liquid fuel such as methanol for cars and trucks. That is among the conclusions in a new report from top authorities on solar energy who met at the 1st Annual Chemical Sciences and Society Symposium. The gathering launched a new effort to initiate international cooperation and innovative thinking on the global energy challenge.
Julie Callahan, Ph.D.,
Image courtesy of
American Chemical Society
A paper describing highlights of the symposium notes that the sun provides more energy to the Earth in an hour than the world consumes in a year. Compare that single hour to the one million years required for Earth to accumulate the same amount of energy in the form of fossil fuels. The paper notes that fossil fuels are not a sustainable resource and urges us to break our dependence on them. Solar energy is among the most promising alternatives.
The scientists pointed out during the meeting that plants use solar energy when they capture and convert sunlight into chemical fuel through photosynthesis. The process involves the conversion of water and carbon dioxide into sugars as well as oxygen and hydrogen. Scientists have been successful in mimicking this fuel-making process, termed artificial photosynthesis, but now must find ways to do so in ways that can be used commercially. Participants described progress toward this goal and the scientific challenges that must be met before solar can be a viable alternative to fossil fuels.
Highlights of the symposium include a talk by Kazunari Domen, Ph.D., of the University of Tokyo in Japan. Domen described his current research on developing more efficient and affordable catalysts for producing hydrogen using a new water-splitting technology called “photocatalytic overall water splitting.” The technology uses light-activated nanoparticles, each 1/50,000th the width of a human hair, to convert water to hydrogen and oxygen. He said that the technique is more efficient and less expensive than current technologies.
Kazunari Domen, Ph.D.,
Image courtesy of
University of Tokyo
- “Scientists have tried for many years to develop a way to split water
molecules, similar to what leaves do during photosynthesis. My new
process captures light and splits water using one device. It is one of
the few water-splitting devices that uses visible light instead of
“Current water-splitting systems have still only less than one percent
solar energy conversion efficiency. We are trying to achieve a much
higher efficiency of between 5 to 10 percent. If we can do that, then
we will have an “artificial leaf” technology that is cheap and practical
to use on a large scale.”
“We are very excited about the future our new “artificial leaf”
technology for helping solve the world’s energy problems. My dream is
to use the device to collect large amounts of solar energy in a desert
area and then use that energy to develop chemical fuels such as
methanol and ammonia. These fuels can then be used to power a car
or generate electricity.”
Julie Callahan, Ph.D., of the ACS Office of International Activities and principal investigator for the project, expressed hope that the solar energy symposium would be the first of an ongoing series of scientific symposia to tackle global challenges of the 21st century.
Here’s Dr. Callahan:
- “Building on the success of this first symposium, we’re now gearing up
for the future, convening top chemical scientists to address other,
equally pressing global challenges. It is an exciting time to be a
That’s the key to solving global challenges of the 21st Century. Be sure to check our other podcasts on fuels [Biofuels and The Sun and More]. Today’s podcast was written by Mark Sampson. I’m Adam Dylewski at the American Chemical Society in Washington.