Coddled crystal slams door on light.A light touch has improved a material designed to manipulate light. The development brings photonic Dealing with light (photons). See photon and photonics. microcircuits, which would use photons instead of electrons, closer to reality, researchers say. To create microchips for light, many researchers have been attempting to create repetitive, crystal-like structures called photonic crystals A nanostructured array of holes used as an optical semiconductor. Just as electronic bandgaps prevent electrons from passing through, photonic crystals create photonic bandgaps that confine light. . Now, Susuma Noda of Kyoto University Kyoto University (京都大学 Kyōto daigaku in Japan and his colleagues report making photonic crystals that approach perfection. The group builds its crystals by positioning strips of semiconductor compounds in a three-dimensional stack known as a woodpile. To end up with woodpiles that are more regular, the scientists realized they needed to reduce flaws that show up during fabrication fabrication (fab´rikā´sh  n),n the construction or making of a restoration. . After examining their previous woodpiles and the methods for making them, the researchers decided on some changes. They lowered the temperature at which they fused the layers and devised a way to etch To create a design in a material by digging out the material. The circuit designs on printed circuit boards and chips are etched by acid. See chip and printed circuit board. away unwanted parts of the structure more gently than before. In the July 28 SCIENCE, the materials researchers claim that their new process produces crystals with "perfect structure from the viewpoint of the optical properties." The ideal photonic crystal totally rejects electromagnetic waves within a band of wavelengths. Indeed, an eight-layer woodpile created with the new process transmits only about 0.01 percent of the light at an important telecommunications wavelength. In contrast, an opal-like photonic crystal unveiled in May by a Spanish-Canadian team transmits 100 times as much light in the same band (SN: 6/17/00, p. 399). However, the opal-style crystal assembles itself from cheap materials, whereas the Japanese team must directly build its crystal at relatively high cost, notes John D. Joannopoulos 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, . "These are both very good advances for their own reasons," he concludes. |
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