Silicon field-effect transistor based on quantum tunneling

J. R. Tucker; Chinlee Wang; P. Scott Carney

doi:10.1063/1.112250

Silicon field-effect transistor based on quantum tunneling

J. R. Tucker
, Chinlee Wang
, P. Scott Carney

Mechanical Engineering

University of Illinois at Urbana-Champaign

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

153 Scopus citations

Abstract

This letter explores regulation of current flow within a silicon field-effect transistor by gate-induced tunneling through a Schottky barrier located at the interface between a metallic source electrode and the Si channel. The goal here is to forestall short-channel effects which are expected to prevent further size reductions in conventional devices when linewidths reach ∼1000 Å. Control of tunneling appears to be possible at minimum channel lengths L∼250 Å or less while simultaneously eliminating the need for large-area source and drain contacts, so that scaling of Si transistors could be significantly extended if this principle proves technically feasible.

Original language	English
Pages (from-to)	618-620
Number of pages	3
Journal	Applied Physics Letters
Volume	65
Issue number	5
DOIs	https://doi.org/10.1063/1.112250
State	Published - 1994

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10.1063/1.112250

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abstract = "This letter explores regulation of current flow within a silicon field-effect transistor by gate-induced tunneling through a Schottky barrier located at the interface between a metallic source electrode and the Si channel. The goal here is to forestall short-channel effects which are expected to prevent further size reductions in conventional devices when linewidths reach ∼1000 {\AA}. Control of tunneling appears to be possible at minimum channel lengths L∼250 {\AA} or less while simultaneously eliminating the need for large-area source and drain contacts, so that scaling of Si transistors could be significantly extended if this principle proves technically feasible.",

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AB - This letter explores regulation of current flow within a silicon field-effect transistor by gate-induced tunneling through a Schottky barrier located at the interface between a metallic source electrode and the Si channel. The goal here is to forestall short-channel effects which are expected to prevent further size reductions in conventional devices when linewidths reach ∼1000 Å. Control of tunneling appears to be possible at minimum channel lengths L∼250 Å or less while simultaneously eliminating the need for large-area source and drain contacts, so that scaling of Si transistors could be significantly extended if this principle proves technically feasible.

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Silicon field-effect transistor based on quantum tunneling

Abstract

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