Electromagnets for micromotors.Electromagnets in the form of coils of copper wire wound around iron cores have long served as crucial components of transformers, relays, electric motors, and other devices. But the difficulty of fabricating such coils, or inductors, on a silicon chip has severely limited their use in electronic circuitry. Now, a team of electrical engineers This is a list of electrical engineers, people who made contributions to electrical engineering or computer engineering.
"We have developed fabrication fabrication (fab´rikā´sh  n),n the construction or making of a restoration. technologies that allow people for the first time to make these devices on the surface of a silicon chip in fully integrated form," says Georgia Tech's Mark G. Allen. "We have made prototype magnetic relays, magnetic micromotors, and microinductors that can be used in voltage converters A voltage converter changes the voltage of an electrical power source and is usually combined with other components to create a power supply. The term "voltage converter" is sometimes used as a generic term for a power supply. ." To make it possible to produce these devices on a silicon chip, the researchers ended up turning the conventional coil inductor inductor, electric device consisting of one or more turns of wire and typically having two terminals. An inductor is usually connected into a circuit in order to raise the inductance to a desired value. inside out, in effect "wrapping" the nickel-iron core around the electrical conductor In science and engineering, conductors, such as copper or aluminum, are materials with atoms have loosely held valence electrons. See electrical conduction. Conductors in context . "From a fabrication point of view, it's easier to wrap a core...around a...zigzag of wire than it is to wrap wire around a planar A technique developed by Fairchild Instruments that creates transistor sublayers by forcing chemicals under pressure into exposed areas. Planar superseded the mesa process and was a major step toward creating the chip. core," Allen says. Yet the magnetic effect remains the same. The fabrication process begins with the deposition of a thick, patterned layer of a nickel-iron alloy atop a silicon surface. This base layer is then coated with an insulating polymer blanket. A carefully positioned mat of zigzagging copper wires makes up the next layer, which is also topped by a polymer coating. Holes drilled vertically through the polymer layers and filled with metal link the base layer with a top layer of nickel-iron alloy to complete the structure. Allowing electrical current to flow through the copper layer turns this microscopic sandwich into a miniature electromagnet electromagnet, device in which magnetism is produced by an electric current. Any electric current produces a magnetic field, but the field near an ordinary straight conductor is rarely strong enough to be of practical use. . This procedure improves on previous fabrication techniques, in which iron cores and electrical windings were constructed separately before being added to electronic circuits. The integrated magnetic inductors also operate at lower voltages than devices based on competing technologies that involve electrostatic forces. Thus, magnetic inductors may prove useful in dust-filled environments, electrically conducting liquids, and other settings in which high voltages are unacceptable. Allen and his coworkers have already demonstrated the potential of their fabrication technique for creating tiny relays, which may someday replace transistors for rapidly switching on or off certain types of high-frequency signals, They have also looked into the possibility of making miniature voltage converters, which could dramatically reduce the size and weight of power supplies for laptop computers and other portable equipment. The same technology has been used to create magnetic micromotors. |
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