Ohm’s Law Survives to the Atomic Scale

Bent Weber; Suddhasatta Mahapatra; Hoon Ryu; S. Lee; Andreas Fuhrer; T. C. G. Reusch; Daniel L. Thompson; W. C. T. Lee; Gerhard Klimeck; Lloyd C. L. Hollenberg; M. Y. Simmons

doi:10.1126/science.1214319

Ohm’s Law Survives to the Atomic Scale

Bent Weber(UNSW Sydney), Suddhasatta Mahapatra(UNSW Sydney), Hoon Ryu(Purdue University West Lafayette), S. Lee(Purdue University West Lafayette), Andreas Fuhrer(UNSW Sydney), T. C. G. Reusch(UNSW Sydney), Daniel L. Thompson(UNSW Sydney), W. C. T. Lee(UNSW Sydney), Gerhard Klimeck(Purdue University West Lafayette), Lloyd C. L. Hollenberg(The University of Melbourne), M. Y. Simmons(UNSW Sydney)

Science

January 6, 2012

10.1126/science.1214319

Cited by 334

Abstract

As silicon electronics approaches the atomic scale, interconnects and circuitry become comparable in size to the active device components. Maintaining low electrical resistivity at this scale is challenging because of the presence of conﬁning surfaces and interfaces. We report on the fabrication of wires in silicon--only one atom tall and four atoms wide--with exceptionally low resistivity (~0.3 milliohm-centimeters) and the current-carrying capabilities of copper. By embedding phosphorus atoms within a silicon crystal with an average spacing of less than 1 nanometer, we achieved a diameter-independent resistivity, which demonstrates ohmic scaling to the atomic limit. Atomistic tight-binding calculations conﬁrm the metallicity of these atomic-scale wires, which pave the way for single-atom device architectures for both classical and quantum information processing.

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