Scaling analysis of electron transport through metal–semiconducting carbon nanotube interfaces: Evolution from the molecular limit to the bulk limit

Yongqiang Xue and Mark A. Ratner
Phys. Rev. B 70, 205416 – Published 16 November 2004

Abstract

We present a scaling analysis of electronic and transport properties of metal-semiconducting carbon nanotube interfaces as a function of the nanotube length within the coherent transport regime, which takes fully into account atomic-scale electronic structure and three-dimensional electrostatics of the metal-nanotube interface using a real-space Green’s function based self-consistent tight-binding theory. As the first example, we examine devices formed by attaching finite-size single-wall carbon nanotubes (SWNT) to both high- and low-work function metallic electrodes through the dangling bonds at the end, where the length of the SWNT molecule varies from the molecular limit to the bulk limit and the strength of metal-SWNT coupling varies from the strong coupling to the weak coupling limit. We analyze the nature of Schottky barrier formation at the metal-nanotube interface by examining the electrostatics, the band lineup and the conductance of the metal-SWNT molecule-metal junction as a function of the SWNT molecule length and metal-SWNT coupling strength. We show that the confined cylindrical geometry and the atomistic nature of electronic processes across the metal-SWNT interface leads to a different physical picture of band alignment from that of the planar metal-semiconductor interface. We analyze the temperature and length dependence of the conductance of the SWNT junctions, which shows a transition from tunneling- to thermal activation-dominated transport with increasing nanotube length. The temperature dependence of the conductance is much weaker than that of the planar metal-semiconductor interface due to the finite number of conduction channels within the SWNT junctions. We find that the current-voltage characteristics of the metal-SWNT molecule-metal junctions are sensitive to models of the potential response to the applied source/drain bias voltages. Our analysis applies in general to devices based on quasi-one-dimensional nanostructures including molecules, carbon nanotubes, and semiconductor nanowires.

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  • Received 22 March 2004

DOI:https://doi.org/10.1103/PhysRevB.70.205416

©2004 American Physical Society

Authors & Affiliations

Yongqiang Xue1,* and Mark A. Ratner2

  • 1College of Nanoscale Science and Engineering, University at Albany-State University of New York, Albany, New York 12203, USA
  • 2Department of Chemistry and Materials Research Center, Northwestern University, Evanston, Illinois 60208, USA

  • *Author to whom correspondence should be addressed. Email address: yxue@uamail.albany.edu. URL: http://www.albany.edu/∼yx152122

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Vol. 70, Iss. 20 — 15 November 2004

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