Device ups hydrogen energy from sunlight.Here's a recipe for a cleaner, healthier planet: Take some water, add solar energy solar energy, any form of energy radiated by the sun, including light, radio waves, and X rays, although the term usually refers to the visible light of the sun. , extract hydrogen, and use it to power fuel cells for running cars and other machines. Then, collect their water emissions and start the procedure again. One look at the list of ingredients in today's fuel cells, however, shows that this ideal isn't yet being followed. Because processes that use sunlight to extract hydrogen remain costly and inefficient, fossil fuels still supply the hydrogen in most fuel cells. Hoping to break the fossil fuel habit, a team of Israeli, German, and Japanese scientists has created a device that boosts the efficiency of solar-powered hydrogen extraction by 50 percent. The group placed a photovoltaic cell A semiconductor diode that converts light into DC voltage. Also known as "solar cells," photovoltaic cells are used in a myriad of applications from simple light sensors to complete energy creation systems. See photovoltaic. on top of two flat, finger-long electrodes. The combination "is very efficient in converting solar energy [into an electric current] but also provides nearly the ideal voltage for splitting water" into hydrogen and oxygen, says team leader Stuart Licht Licht (Light), subtitled "The Seven Days of the Week," is a cycle of seven operas composed by Karlheinz Stockhausen which, in total, lasts over 29 hours. Origin The project, originally titled Hikari of the Technion in Haifa, Israel. A water molecule splits, or undergoes electrolysis electrolysis (ĭlĕktrŏl`əsĭs), passage of an electric current through a conducting solution or molten salt that is decomposed in the process. , at only 1.23 volts. Licht and his colleagues describe their device in the Sept. 14 JOURNAL OF PHYSICAL CHEMISTRY B The Journal of Physical Chemistry B publishes scientific articles reporting research on the chemistry of materials, including nanostructures, macromolecules, statistical mechanics, and the thermodynamics of condensed matter, biophysical chemistry, as well as the structures and . The gadget converts sunlight to an electrolysis current with 18.3 percent efficiency. In turn, the current creates hydrogen gas as it passes through acidic water. The device is "showing the pathway towards higher efficiencies for direct solar-to-hydrogen production," comments John A. Turner of the National Renewable Energy Laboratory The National Renewable Energy Laboratory (NREL), located in Golden, Colorado, as part of the U.S. Department of Energy, is the United States' primary laboratory for renewable energy and energy efficiency research and development. (NREL NREL National Renewable Energy Laboratory NREL Natural Resource Ecology Laboratory (Colorado State University, Fort Collins, CO) ) in Golden, Colo. The newly achieved efficiency may already be high enough for commercial hydrogen generators to be feasible. "That still needs to be figured out," Turner says. In 1998, he and Oscar Khaselev, then also of NREL, demonstrated a novel apparatus for solar-to-hydrogen conversion (SN: 4/18/98, p. 246). To achieve unprecedented efficiency, the device used multiple layers of semiconductor materials Semiconductor materials are insulators at absolute zero temperature that conduct electricity in a limited way at room temperature (see also Semiconductor). The defining property of a semiconductor material is that it can be doped with impurities that alter its electronic properties . The researchers arranged the layers to form two active regions, or junctions, that would absorb solar photons that dislodge electrons. Some of the less energetic photons weren't captured in the first junction but passed to the second, where they generated more current. The design gained an energy advantage by combining solar electricity and water splitting Water splitting is the general term for a chemical reaction in which water is converted into oxygen and hydrogen. Water splitting is actively researched because demand for cheap hydrogen is expected to rise with the new hydrogen economy. into one unit. Their cell's 12.4 percent efficiency--nearly twice that of any previous solar-to-hydrogen device--has held as the record until now. Licht and his colleagues have improved upon that pioneering effort in several crucial ways. In one sense, the NREL device was all wet: It had to be completely immersed in water to operate. That feature forced the researchers to select semiconductors that wouldn't break down in solution. By keeping their stack of semiconductor layers high and dry, Licht and his group were free to optimize them for both converting sunlight to electricity and water splitting. Their design permits a low electrolysis current, which also reduces energy waste. Licht and his coworkers say that besides besting the solar-to-hydrogen conversion record, their work opens the way to efficiencies not considered possible before. Using measured photoelectric efficiencies of seven semiconductor combinations not yet tested in hydrogen generation, they predict maximum solar-to-hydrogen conversion efficiencies of up to 31 percent. Thermodynamics thermodynamics, branch of science concerned with the nature of heat and its conversion to mechanical, electric, and chemical energy. Historically, it grew out of efforts to construct more efficient heat engines—devices for extracting useful work from expanding theory says the maximum could range above 40 percent for a two-junction converter, but no one has previously predicted better than 24 percent performance for practical devices, Turner says. Experimentally achieving the new prediction "would be an accomplishment indeed!" he adds. |
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