Supriyo Datta
Published 2008-09-25, updated 2008-11-03Version 2
Nanoscale electronic devices are of great interest for all kinds of applications like switching, energy conversion and sensing. The objective of this chapter, however, is not to discuss specific devices or applications. Rather it is to convey the conceptual framework that has emerged over the last twenty years, which is important not only because of the practical insights it provides into the design of nanoscale devices, but also because of the conceptual insights it affords regarding the meaning of resistance and the essence of all non-equilibrium phenomena in general. We present a unified description applicable to a wide variety of devices from molecular conductors to carbon nanotubes to silicon transistors covering different transport regimes from the ballistic to the diffusive limit, based on what we call the NEGF-Landauer approach.
Comments: 26 pages, 17 figures. To appear in The Oxford Handbook on Nanoscience and Nanotechnology: Frontiers and Advances, eds. A.V. Narlikar and Y.Y. Fu, volume 1, chapter 1
1/f noise spectroscopy and noise tailoring of nanoelectronic devices
Measuring geometric phases of scattering states in nanoscale electronic devices
Tip-gating Effect in Scanning Impedance Microscopy of Nanoelectronic Devices
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