Call it the anti-sunscreen(遮光剂) . That's more or less the description of what many solar energy researchers would like to find -- light-catching substances that could be added to photovoltaic(光电的) materials in order to convert more of the sun's energy into carbon-free electricity. Research reported in the journal Applied1 Physics Letters, published by the American Institute of Physics (AIP), describes how solar power could potentially be harvested by using oxide2(氧化物) materials that contain the element selenium(硒) . A team at the Lawrence Berkeley National Laboratory in Berkeley, California, embedded3 selenium in zinc4 oxide, a relatively5 inexpensive material that could be promising6 for solar power conversion7 if it could make more efficient use of the sun's energy. The team found that even a relatively small amount of selenium, just 9 percent of the mostly zinc-oxide base, dramatically boosted the material's efficiency in absorbing light.
"Researchers are exploring ways to make solar cells both less expensive and more efficient; this result potentially addresses both of those needs," says author Marie Mayer, a fourth-year University of California, Berkeley doctoral student based out of LBNL's Solar Materials Energy Research Group, which is working on novel materials for sustainable clean-energy sources.
Mayer says that photoelectrochemical water splitting(水光电解法) , using energy from the sun to cleave8 water into hydrogen and oxygen gases, could potentially be the most exciting future application for her work. Harnessing this reaction is key to the eventual9 production of zero-emission hydrogen powered vehicles, which hypothetically(假设地) will run only on water and sunlight. Like most researchers, Mayer isn't predicting hydrogen cars on the roads in any meaningful numbers soon. Still, the great thing about solar power, she says, is that "if you can dream it, someone is trying to research it."