Cycloaddition Chemistry of Organic Molecules with Semiconductor Surfaces
Accounts of Chemical Research2000Vol. 33(9), pp. 617–624
Citations Over TimeTop 1% of 2000 papers
Robert J. Hamers, Sarah K. Coulter, Mark D. Ellison, Jennifer S. Hovis, David F. Padowitz, Michael P. Schwartz, C. Michael Greenlief, John N. Russell
Abstract
Recent investigations have shown that cycloaddition reactions, widely used in organic chemistry to form ring compounds, can also be applied to link organic molecules to the (001) surfaces of crystalline silicon, germanium, and diamond. While these surfaces are comprised of Si=Si, Ge=Ge, and C=C structural units that resemble the C=C bonds of organic alkenes, the rates and mechanisms of the surface reactions show some distinct differences from those of their organic counterparts This article reviews recent studies of [2 + 2], [4 + 2] Diels-Alder, and other cycloaddition reactions of organic molecules with semiconductor surfaces and summarizes the current understanding of the reaction pathways.
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