Nocera and Matthew Kanan, a postdoctoral fellow in Nocera's lab developed a process that will allow the sun's energy to be used to split water into hydrogen and oxygen gases, which later may be recombined inside a fuel cell, creating carbon-free electricity to power houses or electric cars, day or night.

The key component in the process is a catalyst -- cobalt metal, phosphate and an electrode, placed in water -- that produces oxygen gas from water, while another catalyst produces hydrogen gas. When electricity -- whether from a photovoltaic cell, a wind turbine or any other source -- runs through the electrode, the cobalt and phosphate form a thin film on the electrode, and oxygen gas is produced, the researchers explained.

Combined with another catalyst, such as platinum, that can produce hydrogen gas from water, the system can duplicate the water splitting reaction that occurs during photosynthesis.

The new catalyst works at room temperature, in neutral pH water, and is easy to set up, Nocera said. “That’s why I know this is going to work. It’s so easy to implement,” he said.

Nocera also said that sunlight has the greatest potential of any power source to solve the world’s energy problems, since in one hour, enough sunlight strikes the Earth to provide the entire planet's energy needs for one year.

“This is a major discovery with enormous implications for the future prosperity of humankind. The importance of their discovery cannot be overstated since it opens up the door for developing new technologies for energy production thus reducing our dependence for fossil fuels and addressing the global climate change problem,” added James Barber, a leader in the study of photosynthesis, the Ernst Chain Professor of Biochemistry at Imperial College London, and who called the discovery a "giant leap" toward generating clean, carbon-free energy on a massive scale.

While this is a good start, the currently available electrolyzers that split water with electricity and are often used industrially, are not suited for artificial photosynthesis because they are very expensive and require a highly basic (non-benign) environment that has little to do with the conditions under which photosynthesis operates, Nocera said.

As such, more engineering work needs to be done to integrate the new scientific discovery into existing photovoltaic systems, but Nocera is confident that such systems will become a reality.

“This is just the beginning. The scientific community is really going to run with this,” he added.

Nocera hopes that within 10 years homeowners will be able to power their homes in daylight through photovoltaic cells, while using excess solar energy to produce hydrogen and oxygen to power their own household fuel cell. Electricity-by-wire from a central source could be a thing of the past.

The project is part of the MIT Energy Initiative, a program designed to help transform the global energy system to meet the needs of the future and to help build a bridge to that future by improving today's energy systems.

By: DocMemory
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