Nanoscale patterning and oxidation of H-passivated Si(100)-2×1 surfaces with an ultrahigh vacuum scanning tunneling microscope
- 11 April 1994
- journal article
- conference paper
- Published by AIP Publishing in Applied Physics Letters
- Vol. 64 (15) , 2010-2012
- https://doi.org/10.1063/1.111722
Abstract
Nanoscale patterning of the hydrogen terminated Si(100)-2×1 surface has been achieved with an ultrahigh vacuum scanning tunneling microscope. Patterning occurs when electrons field emitted from the probe locally desorb hydrogen, converting the surface into clean silicon. Linewidths of 1 nm on a 3 nm pitch are achieved by this technique. Local chemistry is also demonstrated by the selective oxidation of the patterned areas. During oxidation, the linewidth is preserved and the surrounding H-passivated regions remain unaffected, indicating the potential use of this technique in multistep lithography processes.Keywords
This publication has 15 references indexed in Scilit:
- Fabrication of silicon nanostructures with a scanning tunneling microscopeApplied Physics Letters, 1993
- Selective area oxidation of silicon with a scanning force microscopeApplied Physics Letters, 1993
- Tip-Sample Interactions in the Scanning Tunneling Microscope for Atomic-Scale Structure FabricationJapanese Journal of Applied Physics, 1993
- Role of bond-strain in the chemistry of hydrogen on the Si(100) surfaceSurface Science, 1992
- Field-Induced Nanometer- to Atomic-Scale Manipulation of Silicon Surfaces with the STMScience, 1991
- The importance of structure and bonding in semiconductor surface chemistry: hydrogen on the Si(111)-7 × 7 surfaceSurface Science, 1991
- Atomic-scale conversion of clean Si(111):H-1×1 to Si(111)-2×1 by electron-stimulated desorptionPhysical Review Letters, 1990
- The scanning tunneling microscope as a tool for nanofabricationNanotechnology, 1990
- Modification of hydrogen-passivated silicon by a scanning tunneling microscope operating in airApplied Physics Letters, 1990
- Electronic structures of the monohydride (2×1):H and the dihydrideSi(001) surfaces studied by angle-resolved electron-energy-loss spectroscopyPhysical Review B, 1983