Electromechanical Properties of Metallic, Quasimetallic, and Semiconducting Carbon Nanotubes under Stretching
Top Cited Papers
- 18 April 2003
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 90 (15), 157601
- https://doi.org/10.1103/physrevlett.90.157601
Abstract
An electromechanical system is constructed to explore the electrical properties of various types of suspended single-walled carbon nanotubes under the influence of tensile stretching. Small band-gap semiconducting (or quasimetallic) nanotubes exhibit the largest resistance changes and piezoresistive gauge factors ( to 1000) under axial strains. Metallic nanotubes exhibit much weaker but nonzero sensitivity. Comparison between experiments and theoretical predictions and potential applications of nanotube electromechanical systems for physical sensors (e.g., strain gauges, pressure sensors, etc.) are discussed.
Keywords
This publication has 20 references indexed in Scilit:
- Carbon NanotubesPublished by Springer Nature ,2001
- Band gaps of primary metallic carbon nanotubesPhysical Review B, 2001
- Electronic Structure of Deformed Carbon NanotubesPhysical Review Letters, 2000
- Controllable Reversibility of antoTransition of a Single Wall Nanotube under the Manipulation of an AFM Tip: A Nanoscale Electromechanical Switch?Physical Review Letters, 2000
- Band-gap change of carbon nanotubes: Effect of small uniaxial and torsional strainPhysical Review B, 1999
- Electrical and mechanical properties of distorted carbon nanotubesPhysical Review B, 1999
- Electronic transport in extended systems: Application to carbon nanotubesPhysical Review B, 1999
- The effect of structural distortions on the electronic structure of carbon nanotubesChemical Physics Letters, 1998
- Uniaxial-stress effects on the electronic properties of carbon nanotubesPhysical Review B, 1997
- Size, Shape, and Low Energy Electronic Structure of Carbon NanotubesPhysical Review Letters, 1997