Bell Labs Scientists Find Novel Optical Fibers in Deep-Sea Sponges; Study Reveals How Nature Creates Robust Optical Fibers in Marine Sponges.Business Editors/High-Tech Writers MURRAY HILL Murray Hill may refer to one of the following places:
Scientists from Lucent Technologies' (NYSE NYSE See: New York Stock Exchange : LU) Bell Labs have found that a deep-sea sponge contains optical fiber that is remarkably similar to the optical fiber found in today's state-of-the-art telecommunications networks. The deep-sea sponge's glass fiber, designed through the course of evolution, may possess certain technological advantages over industrial optical fiber, the scientists report in today's issue of the journal Nature. "We believe this novel biological optical fiber may shed light upon new bio-inspired processes that may lead to better fiber optic materials and networks," said Joanna Aizenberg, the Bell Labs materials scientist who led the research team. "Mother Nature's ability to perfect materials is amazing, and the more we study biological organisms, the more we realize how much we can learn from them." The discovery of marine optical fiber is the latest Bell Labs contribution in the emerging field of science known as biomimetics bi·o·mi·met·ics n. (used with a sing. verb) The study of the structure and function of biological systems as models for the design and engineering of materials. , which takes engineering principles from the natural world and applies them to man-made materials and technologies. The sponge in the study, Euplectella, lives in the depths of the ocean in the tropics tropics, also called tropical zone or torrid zone, all the land and water of the earth situated between the Tropic of Cancer at lat. 23 1-2°N and the Tropic of Capricorn at lat. 23 1-2°S. and grows to about half a foot in length. Commonly known as the Venus Flower Basket Venus flower basket or Ve·nus's flower basket also Venus's flower basket n. A sponge of the genus Euplectella, living in deep marine waters of the East Indies and the eastern Asian coast and having a cylindrical skeleton of , it has an intricate cylindrical mesh-like skeleton of glassy silica and a pair of mating shrimp often lives inside it. At the base of the sponge's skeleton is a tuft tuft (tuft) a small clump or cluster; a coil. tuft (toothbrush), n part of the toothbrush head, refers to the small, individual clusters of bristles that proceed from a single opening. of fibers that extends outward like an inverted inverted reverse in position, direction or order. inverted L block a pattern of local filtration anesthesia commonly used in laparotomy in the ox. crown. Typically, these fibers are between two and seven inches long and about the thickness of a human hair. The Bell Labs team found that each of the sponge's fibers comprises of distinct layers with different optical properties. Concentric silica cylinders with high organic content surround an inner core of high-purity silica glass, a structure similar to industrial optical fiber, in which layers of glass cladding surround a glass core of slightly different composition. The researchers found during experiments that the biological fibers of the sponge conducted light beautifully when illuminated, and used the same optical principles that modern engineers have used to design industrial optical fiber. "These biological fibers bear a striking resemblance to commercial telecommunications fibers, as they use the same material and have similar dimensions," said Aizenberg. Though these natural bio-optical fibers do not have the superbly high transparency needed for modern telecommunication networks, the Bell Labs researchers found that these fibers do have a big advantage in that they are extremely resilient to cracks and breakage. Although extremely reliable, one of the main causes for outages in commercial optical fiber is fracture resulting from crack growth within the fiber. Infrequent as an outage is, when it occurs, replacing the fiber is often a costly, labor-intensive proposition, and scientists have sought to make fiber that is less susceptible to this problem. The sponge's solution is to use an organic sheath to cover the biological fiber, Aizenberg and her colleagues discovered. "These bio-optical fibers are extremely tough," she said. "You could tie them in tight knots and, unlike commercial fiber, they would still not crack. Maybe we can learn how to improve on existing commercial fiber from studying these fibers of the Venus Flower Basket," she said. Another advantage of these biological fibers is that they are formed by chemical deposition at the temperature of seawater seawater Water that makes up the oceans and seas. Seawater is a complex mixture of 96.5% water, 2.5% salts, and small amounts of other substances. Much of the world's magnesium is recovered from seawater, as are large quantities of bromine. . Commercial optical fiber is produced with the help of a high-temperature furnace and expensive equipment. Aizenberg said, "If we can learn from nature, there may be an alternative way to manufacture fiber in the future." Should scientists succeed in emulating these natural processes, they may also help reduce the cost of producing optical fiber. "This is a good example where Mother Nature can help teach us about engineering materials," said Cherry Murray, senior vice president of physical sciences research at Bell Labs. "In this case, a relatively simple organism has a solution to a very complex problem in integrated optics Combining electrical and optical components on the same silicon-based substrates used in the fabrication of a semiconductor chip. Also called "silicon photonics," fiber-optic communications employs numerous integrated optics devices, including lasers, photodetectors, beam splitters, and materials design. By studying the Venus Flower Basket, we are learning about low-cost ways of forming complex optical materials Optical materials All substances used in the construction of devices or instruments whose function is to alter or control electromagnetic radiation in the ultraviolet, visible, or infrared spectral regions. at low temperatures. While many years away from being applied to commercial use, this understanding could be very important in reducing the cost and improving the reliability of future optical and telecommunications equipment." Other members of the research team were Bell Labs materials scientists Vikram Sundar and John Grazul, as well as zoologist Micha Ilan of Tel Aviv University Tel Aviv University (TAU, אוניברסיטת תל־אביב, את"א) is Israel's largest on-site university. and optics researcher Andrew Yablon of OFS (OFS, Norcross, GA, www.ofsbrightwave.com) A manufacturer of optical fibers and interconnect equipment. Formerly the Optical Fiber Solutions (OFS) Group of Lucent, OFS was turned into a stand-alone company acquired by Furukawa Electric in 2001. Laboratories. The study of biomimetics at Bell Labs is part of the quest to find better materials for technology and industry, and has proved remarkably fruitful. Two years ago, Aizenberg and her collaborators made the surprising discovery that thousands of chalk-like calcite calcite (kăl`sīt), very widely distributed mineral, commonly white or colorless, but appearing in a great variety of colors owing to impurities. crystals spread throughout the exoskeletons of brittlestars, starfish-like marine invertebrates, collectively form an unusual kind of compound eye for the animals. The brittlestar's calcite microlenses expertly compensate for birefringence Birefringence The splitting which a wavefront experiences when a wave disturbance is propagated in an anisotropic material; also called double refraction. In anisotropic substances the velocity of a wave is a function of displacement direction. and spherical aberration spherical aberration: see aberration, in optics. , two common types of distortions in lenses. This led the Bell Labs scientists to attempt to mimic nature's success and design crystals based on the brittlestar brittlestar, common name for echinoderms belonging to the class Ophiuroidea. The name is derived from their habit of breaking off arms as a means of defense. New arms are easily regenerated. model, with the ultimate goal of building complex arrays of microlenses similar to the brittlestar's own lenses. Earlier this year, Aizenberg and her colleagues developed a new crystallization Crystallization The formation of a solid from a solution, melt, vapor, or a different solid phase. Crystallization from solution is an important industrial operation because of the large number of materials marketed as crystalline particles. approach that allowed them to directly fabricate single crystals of calcite that were about one-tenth of a centimeter across. These had patterns less than ten micrometers across, which is approximately one-tenth the diameter of a human hair -- an approach that may revolutionize how crystals are made in the future for a wide variety of applications. Single crystals patterned at the micron scale or smaller and integrated into opto-electronic circuits are important components needed to engineer highly advanced electronic, sensory and optical devices. Bell Labs is the leading source of new communications technologies. It has generated more than 30,000 patents since 1925 and has played a pivotal role in inventing or perfecting key communications technologies, including transistors, digital networking and signal processing See DSP. , lasers and fiber-optic communications systems, communications satellites, cellular telephony, electronic switching of calls, touch-tone dialing, and modems. Bell Labs scientists have received six Nobel Prizes in Physics, nine U.S. National Medals of Science and eight U.S. National Medals of Technology(R). For more information about Bell Labs, visit its Web site at http://www.bell-labs.com. Lucent Technologies, headquartered in Murray Hill, N.J., USA, designs and delivers networks for the world's largest communications service providers. Backed by Bell Labs research and development, Lucent relies on its strengths in mobility, optical, data and voice networking technologies as well as software and services to develop next-generation networks. The company's systems, services and software are designed to help customers quickly deploy and better manage their networks and create new, revenue-generating services that help businesses and consumers. For more information on Lucent Technologies, visit its Web site at http://www.lucent.com. |
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