New patterning technique produces a faithful
reproduction of grayscale images down to the micrometer level
In his
1959 lecture There's Plenty of Room at the Bottom, the US physicist Richard
Feynman asked the question: “Why cannot we write the entire 24 volumes of the
Encyclopaedia Britannica on the head of a pin?” Since then, scientists have
made great advances in the nascent field of nanotechnology — and among them,
the reading and writing of features at the atomic scale.
Current
techniques for patterning features at the atomic scale, however, have been
limited by their ability to replicate colors or grayscale information. Joel
Yang at the A*STAR Institute of Materials Research and Engineering and
co-workers1 have now developed a patterning technique that produces a faithful
reproduction of grayscale images with accuracy down to tens of micrometers.
Conventional
micro-patterning techniques typically build on halftone printing, whereby the
brightness of the image is generated by varying the density of monochromatic
elements. Yang’s technique considers these elements as ‘nanoposts’ — posts of
only ten nanometers in size — that are arranged in one of 17 possible patterns
or ‘shades’. It then produces faithful reproductions of grayscale images using
these 17 shades in hand.
As a
proof of principle, the researchers replicated the patterns of a test image
(pictured) onto an area of 40 square micrometers. In the densest region, the
separation between individual dots was a mere 10 nanometers.
The
halftone technique had been used before to create grayscale optical
micrographs. However, Yang and colleagues have now pushed the approach into the
realm of electron microscopy: “Our technique utilizes an
electron-beam-lithography method with one of the best resolutions, allowing us
to create grayscale images that are highly miniaturized,” explains Yang. “The
method should be useful for creating images that can be seen under an optical
microscope and may open up new avenues to adding colors to images.”
Yang
and his team envisioned several uses of the miniaturized images, for example,
in anti-counterfeit features to nanophotonic devices. “But above all, these are
striking images,” says Yang. Indeed, one of the images — a 4000-fold
miniaturization of M. C. Escher’s mezzotint Dewdrop — has won last year’s Grand
Prize Award of the International Conference on Electron, Ion, and Photon Beam
Technology and Nanofabrication (EIPBN) conference. "Winning that award was
a thrilling experience especially as it was presented by a community of
nanofabrication experts", says Yang. "One who stares enough into the
screen of a scanning electron microscope would appreciate the intrigue and
aesthetic beauty of these micrographs. It is rare to see a
scanning-electron-microscope image of a photo-realistic person staring back at
you from the nanoworld."
The
A*STAR-affiliated researchers contributing to this research are from the Institute of Materials Research and
Engineering
References
- Yang, J. K. W.,
Duan, H., Law, J. B. K. , Low, H. Y. & Cord, B. Miniaturization of
grayscale images. Journal of Vacuum Science and Technology B 29,
06F313 (2011). | article
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