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| Nanofabrication Technology: A View of the Future |
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SPEAKER:
Grant Willson
Professor of Chemical Engineering
Rashid Engineering Regents Chair, University of Texas
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ABOUT THE LECTURE:
In a lecture that dips into both the anatomy and history of the semiconductor, Grant Willson offers some provocative thoughts on whether industry can continue improving on this most useful of inventions.
He describes how steady advances in miniaturization enabled the astonishing progress of microchips over the past 40 years. Today, says Willson, you can “buy a transistor for less than the cost of a single written character in your local newspaper.” When he began at IBM in the 1970s, the silicon wafers produced were only 1 ¼ inches in diameter; now “they’re bigger than pizzas.”
Willson delves into the technological changes that both enabled printing on circuits to grow smaller, and the final product to grow larger. He details the original process of photolithography, involving designing a circuit pattern, then using a $25 million printer with a focused electron beam to reproduce the pattern on special glass, called a mask. It’s the mask’s pattern, etched onto a silicon wafer that forms the basis of the microchip. Layer after layer of these patterns get laid down on a single chip.
The machines behind these processes cost tens of millions of dollars. Just the lens for focusing laser light onto the wafer through the mask has 40 optical elements and weighs as much as a car. Over time, explains Wilson, “People try to make bigger lenses to make smaller structures. The bigger the lens, the shorter the wavelength of light.” In the ‘70s, recounts Wilson, machines were printing hundreds of miles of stuff the size of a bacterium. Today, with the help of chemical catalysts, printing has been reduced to less than 100 nanometers in diameter.
But there’s a problem in reaching the next generation of super-small, mass-produced chips, believes Willson. Major manufacturers are investing hundreds of millions to figure out the right method to enable light to burn ever more Lilliputian lines on chips. “Even if they succeed in building this tool, they will lose. Chemistry will defeat them in the end, and the machine will never work.” According to Willson, the chemical catalyst diffuses and there’s blurring of lines that should be sharp. Furthermore, a single machine of this type would cost $80 million, says Willson, putting production costs ludicrously high.
So has the march of improvement in semiconductor technology ended? Willson sees hope yet, in the form of Step and Flash Imprint lithography (S-FIL), a new approach to high resolution patterning, which can replicate shapes as small as 10 nanometers and at reasonable cost.
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ABOUT THE SPEAKER:
Grant Willson joined the faculties of the Departments of Chemical Engineering and Chemistry at the University of Texas at Austin in 1993. He came to the University of Texas from his position as an IBM Fellow and Manager of the Polymer Science and Technology area at the IBM Almaden Research Center in San Jose, California.
He is a member of the National Academy of Engineering, among many professional organizations. He serves on the editorial boards of several journals in polymer chemistry and materials science and is co-author of more than 300 journal publications. He is editor and author of several books and co-inventor on more than 25 issued patents. Willson is the recipient of the 1999 National Academy of Sciences Award for Chemistry in Service to Society.
Willson received his B.S. and Ph.D. in Organic Chemistry from the University of California at Berkeley and an M.S. degree in Organic Chemistry from San Diego State University.
Willson's UT website
NOTES ON THE VIDEO (Time Index):
Video length is 1:16:09.
Karl K. Berggren, Emanuel E. Landsman Associate Professor of Electrical Engineering, introduces the lecture series, thanks the sponsors and organizers. He then introduces Henry Smith, Professor of Electrical Engineering.
At 2:43, Smith introduces Grant Willson.
At 5:23, Willson begins.
At 1:0710, Q&A begins.
The information on this page was accurate as of the day the video was added to MIT World. This video was added to MIT World on 2007-10-04.
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