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Posted: December 26, 2008
Nano-patterning on silicon - writing between the lines
(Nanowerk News) Miniaturization of microprocessor components can be achieved by two opposing methods: so-called top-down and bottom-up approaches. In top-down approaches, smaller and smaller circuits are produced by optimizing and improving upon larger scale patterning technology. Bottom-up approaches rely on the assembly of single molecule building blocks to produce patterns—ultimately, the pattern size that can be achieved by either method will coincide.
One potential bottom-up method creates molecular lines—and ultimately patterns—by reacting molecules with the atoms at the surface of a material. The major challenge for researchers is to control the direction in which these lines grow.
Scanning-tunneling microscopy image of acetophenone lines on a silicon surface. The lines of acetophenone can be seen as a bright orange line against the blue background of the surface. (Image: RIKEN)
The surface of the silicon comprises pairs of silicon atoms, known as dimers, arranged in parallel rows. Various molecules have been previously shown to form straight lines by reaction with the surface of the silicon—either along the dimer rows or perpendicular to them. Importantly, the direction of growth of these lines depended—until now—only on the molecule reacting with the silicon surface.
The silicon surface is prepared by reaction with atomic hydrogen, which results in silicon hydrogen bonds over most of the surface. However a few silicon atoms do not react, forming so called dangling bond sites, which are very reactive. Acetophenone molecules react with the dangling bond and go on to create a new dangling bond site at an adjacent silicon dimer. This sets up a chain reaction and produces a molecular line. The direction in which the lines of molecules grow depends on whether the new dangling bond is formed in a silicon dimer in the same row or a parallel row.
The distance between silicon dimers in the same row or those in adjacent rows is different, and there is a consequent energy difference in the two possible growth directions.
“Acetophenone happens to have a geometry that means it can grow lines in either direction,” explains Hossain. “Creation of a chiral center upon adsorption also seems to play important role in producing lines in both directions, which we believe will provide opportunities to control the growth direction.”