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New Lithography Method Creates Molecule-Sized Images

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EVANSTON, Ill., Sept. 29, 2006 -- Ever since the invention of the first scanning probe microscope in 1981, researchers have believed the powerful tool would someday be used for the nanofabrication and nanopatterning of surfaces in a molecule-by-molecule, bottom-up fashion. Despite 25 years of research in this area, scientists had hit a brick wall in developing a technique with commercial potential -- until now.

Northwestern University researchers have developed a 55,000-pen, two-dimensional array that allows them to simultaneously create 55,000 identical patterns drawn with tiny dots of molecular ink on substrates of gold or glass, with each structure being only a single molecule tall. This advance of a patterning method called dip-pen nanolithography (DPN), which was invented at Northwestern in 1999, was published online Monday by the journal Angewandte Chemie.

The background shows some of the 55,000 miniature images of a 2005 US nickel made with dip-pen lithography. (Each circle is only twice the diameter of a red blood cell.) Each nickel image with Thomas Jefferson's profile (in red) is made of a series of 80-nm dots. The inset (right) is an electron microscope image of a portion of the 55,000-pen array.
To demonstrate the technique's power, the researchers reproduced the face of Thomas Jefferson from a five-cent coin 55,000 times, which took 30 minutes. Each identical nickel image is 12 µm wide -- about twice the diameter of a red blood cell -- and is made up of 8773 dots, each 80 nm in diameter.

The parallel process paves the way for making DPN competitive with other optical and stamping lithographic methods used for patterning large areas on metal and semiconductor substrates, including silicon wafers. The advantage of DPN, which is a maskless lithography, is that it can be used to deliver many different types of inks simultaneously to a surface in any configuration one desires. Mask-based lithographies and stamping protocols are extremely limited in this regard.

"This development should lead to massively miniaturized gene chips, combinatorial libraries for screening pharmaceutically active materials and new ways of fabricating and integrating nanoscale or even molecular-scale components for electronics and computers," said Chad A. Mirkin, director of Northwestern's International Institute for Nanotechnology and George B. Rathmann Professor of Chemistry, who led the research.

"In addition, it could lead to new ways of studying biological systems at the single particle level, which is important for understanding how cancer cells and viruses work and for getting them to stop what they do," he said. "Essentially one can build an entire gene or protein chip that fits underneath a single cell."

In addition to Mirkin, other authors on the paper are Khalid Salaita (lead author), Yuhuang Wang and Rafael A. Vega from Northwestern; Joseph Fragala from NanoInk, Inc.; and Chang Liu of the University of Illinois at Urbana-Champaign.

The research was supported by the National Institutes of Health, DARPA, the Air Force Office of Scientific Research and the National Science Foundation. For more information, visit:
Sep 2006
1. A single unit in a device for changing radiant energy to electrical energy or for controlling current flow in a circuit. 2. A single unit in a device whose resistance varies with radiant energy. 3. A single unit of a battery, primary or secondary, for converting chemical energy into electrical energy. 4. A simple unit of storage in a computer. 5. A limited region of space. 6. Part of a lens barrel holding one or more lenses.
In optics, an image is the reconstruction of light rays from a source or object when light from that source or object is passed through a system of optics and onto an image forming plane. Light rays passing through an optical system tend to either converge (real image) or diverge (virtual image) to a plane (also called the image plane) in which a visual reproduction of the object is formed. This reconstructed pictorial representation of the object is called an image.
An instrument consisting essentially of a tube 160 mm long, with an objective lens at the distant end and an eyepiece at the near end. The objective forms a real aerial image of the object in the focal plane of the eyepiece where it is observed by the eye. The overall magnifying power is equal to the linear magnification of the objective multiplied by the magnifying power of the eyepiece. The eyepiece can be replaced by a film to photograph the primary image, or a positive or negative relay...
arrayBasic Scienceblood cellCelldip-pen lithographyDPNimageindustrialJeffersonlithographymicroscopeMicroscopyminiatureMirkinmoleculenanolithographyNews & FeaturesnickelNorthwesternstamping

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