Schottky-to-ohmic crossover in carbon nanotube transistor contacts

V. Perebeinos; J. Tersoff; W. Haensch

doi:10.1103/PhysRevLett.111.236802

Schottky-to-ohmic crossover in carbon nanotube transistor contacts

V. Perebeinos
, J. Tersoff
, W. Haensch

Department of Electrical Engineering

IBM

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

For carbon nanotube transistors, as for graphene, the electrical contacts are a key factor limiting device performance. We calculate the device characteristics as a function of nanotube diameter and metal work function. Although the on-state current varies continuously, the transfer characteristics reveal a relatively abrupt crossover from Schottky to Ohmic contacts. We find that typical high-performance devices fall surprisingly close to the crossover. Therefore, tunneling plays an important role even in this regime, so that current fails to saturate with gate voltage as was expected due to "source exhaustion."

Original language	English
Article number	236802
Journal	Physical Review Letters
Volume	111
Issue number	23
DOIs	https://doi.org/10.1103/PhysRevLett.111.236802
State	Published - Dec 4 2013

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10.1103/PhysRevLett.111.236802

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N2 - For carbon nanotube transistors, as for graphene, the electrical contacts are a key factor limiting device performance. We calculate the device characteristics as a function of nanotube diameter and metal work function. Although the on-state current varies continuously, the transfer characteristics reveal a relatively abrupt crossover from Schottky to Ohmic contacts. We find that typical high-performance devices fall surprisingly close to the crossover. Therefore, tunneling plays an important role even in this regime, so that current fails to saturate with gate voltage as was expected due to "source exhaustion."

AB - For carbon nanotube transistors, as for graphene, the electrical contacts are a key factor limiting device performance. We calculate the device characteristics as a function of nanotube diameter and metal work function. Although the on-state current varies continuously, the transfer characteristics reveal a relatively abrupt crossover from Schottky to Ohmic contacts. We find that typical high-performance devices fall surprisingly close to the crossover. Therefore, tunneling plays an important role even in this regime, so that current fails to saturate with gate voltage as was expected due to "source exhaustion."

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Schottky-to-ohmic crossover in carbon nanotube transistor contacts

Abstract

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