HyperSolar Moves Closer to Low-Cost Solar Hydrogen Water-Splitting by Reaching the 1.0 Volt Milestone
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HyperSolar, Inc. today announced that its artificial photosynthesis technology is now capable of producing 1.0 volt open circuit voltage for use in direct solar hydrogen production. This achievement represents a dramatic voltage increase over the previous 0.2 volt just 8 months ago, and 0.75 volt just 3 months ago The post HyperSolar Moves Closer to Low-Cost Solar Hydrogen Water-Splitting by Reaching the 1.0 Volt Milestone appeared first on Green Building Elements .
Company also extends sponsored research agreement with University of California Santa Barbara after achieving dramatic breakthroughs in its novel low-cost solar cell component
HyperSolar, Inc. today announced that its artificial photosynthesis technology is now capable of producing 1.0 volt open-circuit voltage for use in direct solar hydrogen production. This achievement represents a dramatic voltage increase over the previous 0.2 volt just 8 months ago, and 0.75 volt just 3 months ago.
It is well known that the theoretical voltage for splitting water into hydrogen and oxygen is 1.23 volts, and approximately 1.5 volts in real-world systems. Achieving 1.5 volts using inexpensive solar cells has eluded the world. For example, silicon solar cells are the most inexpensive and abundant, but their 0.7 volt is not enough to split water. Commercially available high voltage solar cells are unfortunately too expensive for use in hydrogen production.
“Our cutting-edge research program at the University of California Santa Barbara led by Dr. Syed Mubeen Hussaini continues to make impressive progress,” stated Tim Young, CEO of HyperSolar. “The 1.0 volt milestone is very exciting in that it provides us with a clear and encouraging roadmap to reach the 1.5 volts needed for water splitting. The semi-conductor materials used are very inexpensive, which gives us confidence that a low-cost system is possible. The process to make this novel solar cell is equally exciting in that it is a simple solutions-based chemistry process. It does not require conventional expensive semiconductor processes and facilities. It was literally made in a beaker.”
Mr. Young continued, “Recently, Honda and General Motors announced a partnership to bring hydrogen cars to the mass market by 2020. While this is great news for our industry, a major unsolved piece of the puzzle is the low-cost production of renewable hydrogen for fueling stations. We believe that producing renewable hydrogen anywhere there is water and sunlight is the key to realizing a cost-effective hydrogen economy of fuel cell vehicles. We envision that fueling stations can be built next to self-contained solar hydrogen production plants using our low-cost technology.”
HyperSolar’s research is centered on developing a low-cost and submersible hydrogen production particle that can split water molecules under the sun, emulating the core functions of photosynthesis. Each particle is a complete hydrogen generator that contains a novel high voltage solar cell bonded to chemical catalysts by a proprietary encapsulation coating.
A video of an early proof-of-concept prototype can be viewed at http://hypersolar.com/application.php. HyperSolar recently extended its sponsored research agreement with UCSB to further the development.
While 1.0 volt may not be commercially viable for water splitting, it is viable in high value photo-catalysis application in the chemical industry, such as bromine extraction from wastewater. HyperSolar intends to explore those opportunities as part of its overall commercialization strategy.
Source: Business Wire