Heart of the matter: scanning scope digs deeper into microchips.Princesses may feel peas under huge stacks of mattresses, but semiconductor manufacturers have a much harder time detecting minuscule minuscule Lowercase letters in calligraphy, in contrast to majuscule, or uppercase letters. Unlike majuscules, minuscules are not fully contained between two real or hypothetical lines; their stems can go above or below the line. defects within the crystalline Like a crystal. It implies a uniform structure of molecules in all dimensions. For example, phase change technology, widely used for rewritable optical discs, uses crystalline spots (bits) to reflect the laser beam. Amorphous, non-crystalline bits do not reflect light. layers of their microchips. So, they have difficulty determining when something goes wrong in the manufacturing process. Now, researchers have developed a noninvasive imaging technique that lets them sec deep inside a chip. Scanning-probe microscopy microscopy /mi·cros·co·py/ (mi-kros´kah-pe) examination under or observation by means of the microscope. mi·cros·co·py n. 1. The study of microscopes. 2. , a family of techniques that can portray surfaces in exquisite detail, is routinely used for analyzing chip materials. But defects that are buried more than 5 to 10 nanometers below the surface are "pretty much impossible to see," says Vinayak P. Dravid, a materials scientist at Northwestern University Northwestern University, mainly at Evanston, Ill.; coeducational; chartered 1851, opened 1855 by Methodists. In 1873 it absorbed Evanston College for Ladies. in Evanston, Ill. To give depth perception to their scanning-probe microscope system, Dravid and his colleague Gajendra S. Shekhawat rely on acoustic waves. A so-called sample wave travels through a specimen from below and meets another acoustic wave emitted from the microscope's probe above the sample. When the sample wave encounters defects, its frequency and amplitude change, and that disturbance is carried into the interference pattern interference pattern An overall pattern that results when two or more waves interfere with each other, generally showing regions of constructive and of destructive interference. generated by the two waves, explains Dravid. The scanning-probe tip, which also acts as a receiver, "listens to these slight perturbations," he says. The probe transmits information to a computer, which then depicts the specimen's interior. "I think [the technique] opens some really exciting avenues," says Robert Geer, a materials scientist at the State University of New York (body) State University of New York - (SUNY) The public university system of New York State, USA, with campuses throughout the state. at Albany. One challenge now, he notes, is to identify how various material flaws, such as voids and extra atoms, show up in the images. Dravid and Shekhawat, who describe their work in the Oct. 7 Science, have detected gold nanoparticles that they had implanted under a 500-nm polymer layer as a test. They also used the technique to find holes buried in a structure of peaks and valleys that is created as an intermediate step during a chip's manufacture. Such holes, if undetected, would reduce a chip's performance, says Dravid. "It's the first method I've seen to directly image these subsurface sub·sur·face adj. Of, relating to, or situated in an area beneath a surface, especially the surface of the earth or of a body of water. Adj. 1. voids in an opaque material nondestructively," says Alain C. Diebold of SEMATECH SEMATECH Semiconductor Manufacturing Technology , a consortium of semiconductor manufacturers. "This kind of tool could have a lot of applications in research and development for the semiconductor industry." Along with imaging microelectronic components, Dravid expects his system to be useful in biological research. Unlike other scanning-probe microscopes, the acoustically enhanced system doesn't require the tip to come in contact with the surface. Therefore, et tan be used on "soft" structures, such as cells, says Dravid. |
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