Protein power: solar cell produces electricity from spinach and bacterial proteins.Inspired by the efficiency with which plants convert sunlight into sugar, researchers have fabricated a solar cell solar cell, semiconductor devised to convert light to electric current. It is a specially constructed diode, usually made of silicon crystal. When light strikes the exposed active surface, it knocks electrons loose from their sites in the crystal. that uses photosynthetic proteins to convert light into electricity. Although the prototype device can't yet rival commercial solar cells made of silicon, it demonstrates a new strategy for making longer-lasting photovoltaic cells. To make the solar cell, a team of biologists and engineers led by Mare Baldo of the Massachusetts Institute of Technology Massachusetts Institute of Technology, at Cambridge; coeducational; chartered 1861, opened 1865 in Boston, moved 1916. It has long been recognized as an outstanding technological institute and its Sloan School of Management has notable programs in business, (MIT MIT - Massachusetts Institute of Technology ) harvested photosynthetic proteins from spinach and the bacterium Rhodobacter sphaeroides and deposited the proteins onto a glass support. Because the proteins naturally reside in an aqueous environment inside a cell membrane Cell membrane The membrane that surrounds the cytoplasm of a cell; it is also called the plasma membrane or, in a more general sense, a unit membrane. This is a very thin, semifluid, sheetlike structure made of four continuous monolayers of molecules. , it took some creative chemistry to keep the approximately 2 billion isolated proteins functional on a solid surface. Consider the new material that MIT molecular biologist Shuguang Zhang developed to stabilize the proteins. It consists of synthetic peptides that self-assemble into structures resembling cell membranes. When embedded in the synthetic membranes, the photosynthetic proteins retain their function. The MIT group placed a thin layer of this membrane complex on a glass surface coated with indium tin oxide Indium tin oxide (ITO, or tin-doped indium oxide) is a mixture of indium(III) oxide (In2O3) and tin(IV) oxide (SnO2), typically 90% In2O3, 10% SnO2 by weight. , which served as a transparent electrode. The researchers then added a soft layer of an organic semiconductor and topped it all with a silver electrode. When the researchers shone light of certain wavelengths onto the device, the photosynthetic proteins absorbed the photons and shunted excited electrons through the semiconductor layer and into the silver electrode, creating a current. Baldo and his colleagues describe the working device in an upcoming issue of Nano Letters. "This is very exciting work" says Peter Peumans of Stanford University Stanford University, at Stanford, Calif.; coeducational; chartered 1885, opened 1891 as Leland Stanford Junior Univ. (still the legal name). The original campus was designed by Frederick Law Olmsted. David Starr Jordan was its first president. , noting that the new strategy opens many possibilities for making not just solar cells but also other protein-based electronic devices. However, he says, to make a useful solar cell, the MIT team will have to dramatically increase the device's efficiency. To boost the solar cell's power output, Baldo and his colleagues are exploring ways of packing more photosynthetic proteins into their 1-millimeter-by-l-millimeter device. One potential way of achieving that goal is to roughen rough·en tr. & intr.v. rough·ened, rough·en·ing, rough·ens To make or become rough. roughen Verb to make or become rough Verb 1. the glass to increase the amount of surface area that can hold the proteins. Even if Baldo and his colleagues can't boost their new solar cell's efficiency to match that of commercial photovoltaic The generation of voltage by a material that is exposed to light in the visible and invisible ranges. See photoelectric and photovoltaic cell. devices, there could be other advantages to a protein-based design. For example, many solar cell materials degrade overtime, but a protein-based solar cell could be self-repairing, says Baldo. Just as living plants replenish their photosynthetic proteins by swapping out the old copies for new ones, it might become possible to flush a solution of fresh proteins through a solar cell to replace the photosynthetic molecules as they degrade, Baldo explains. Stephen Forrest of Princeton University Princeton University, at Princeton, N.J.; coeducational; chartered 1746, opened 1747, rechartered 1748, called the College of New Jersey until 1896. Schools and Research Facilities says that experiments such as Baldo's could also give researchers a greater understanding of the mechanisms underlying photosynthesis. "Nature has taken a very long time to optimize solar energy collection and conversion" he says, "and it has many strategies for doing that." |
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