M. Simmons, F. Rueß, W. Pok, D. Thompson, M. Fuchsle, Giordano Scappucci, T. Reusch, K. Goh, S. R. Schofield, B. Weber, L. Oberbeck, A. Hamilton, F. Ratto
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An important driving force behind the microelectronics industry is the ability to pack ever more features onto a silicon chip, by continually miniaturising the individual components. However, after 2015 there is no known technological route to reduce devices below 10 nm. We demonstrate a complete fabrication strategy towards atomic-scale device fabrication in silicon using phosphorus as a dopant in combination with scanning probe lithography and high purity, low temperature crystal growth. A major advantage of this strategy is the ability to investigate the role of dopant placement and atomically controlled growth on electronic device operation.
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