Negative stiffness and enhanced damping of individual multiwalled carbon nanotubes

Loading...
Thumbnail Image

Embargo Date

Related Collections

Degree type

Discipline

Subject

composite materials
axial-compression
instabilities
diamond
strain
phase

Funder

Grant number

License

Copyright date

Distributor

Related resources

Author

Yap, H W
Lakes, R S

Contributor

Abstract

The mechanical instabilities and viscoelastic response of individual multiwalled carbon nanotubes and nanofibers (MWCNTs/Fs) under uniaxial compression are studied with atomic force microscopy. Specific buckling events are evident by regimes of negative stiffness, i.e., marked drops in force with increasing compression. Uniaxial cyclic loading can be repeatedly executed even in initially postbuckled regimes, where the CNTs/Fs display incremental negative stiffness. Increases in mechanical damping of 145–600 % in these initially postbuckled regimes, as compared to the linear prebuckled regimes, are observed. Increased damping is attributed to frictional energy dissipation of walls in buckled configurations of the MWCNTs/Fs. This represents the extension of the concept of negative stiffness to the scale of nanostructures and opens up possibilities for designing nanocomposites with high stiffness and high damping simultaneously.

Advisor

Date Range for Data Collection (Start Date)

Date Range for Data Collection (End Date)

Digital Object Identifier

Series name and number

Publication date

2008-01-24

Journal title

Volume number

Issue number

Publisher

Publisher DOI

Journal Issues

Comments

Copyright American Physical Society. Reprinted from Physical Review B, Volume 77, Issue 4, Article 045423, 7 pages. Publisher URL: http://dx.doi.org/10.1103/PhysRevB.77.045423

Recommended citation

Collection