Extreme Energy Dissipation via Material Evolution in Carbon Nanotube Mats.

abstract

Thin layered mats comprised of an interconnected meandering network of multiwall carbon nanotubes (MWCNT) are subjected to a hypersonic micro-projectile impact test. The mat morphology is highly compliant and while this leads to rather modest quasi-static mechanical properties, at the extreme strain rates and large strains resulting from ballistic impact, the MWCNT structure has the ability to reconfigure resulting in extraordinary kinetic energy (KE) absorption. The KE of the projectile is dissipated via frictional interactions, adiabatic heating, tube stretching, and ultimately fracture of taut tubes and the newly formed fibrils. The energy absorbed per unit mass of the film can range from 7-12MJ kg-1, much greater than any other material.

authors

Thomas, Edwin

published proceedings

Adv Sci (Weinh)

altmetric score

20.45

author list (cited authors)

Hyon, J., Lawal, O., Thevamaran, R., Song, Y. E., & Thomas, E. L.

citation count

3

complete list of authors

Hyon, Jinho||Lawal, Olawale||Thevamaran, Ramathasan||Song, Ye Eun||Thomas, Edwin L

publication date

March 2021

publisher

Wiley Publisher

published in

Advanced Science Journal

keywords

Carbon Nanotube Mats
Extreme Energy Absorption
High Strain Rate Deformation
Laser Induced Projectile Impact Test

PubMed Central ID

33747728

Digital Object Identifier (DOI)

10.1002/advs.202003142

start page

2003142

end page

2003142

volume

8

issue

6

URL

http://dx.doi.org/10.1002/advs.202003142

Extreme Energy Dissipation via Material Evolution in Carbon Nanotube Mats. Academic Article

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abstract

authors

published proceedings

altmetric score

author list (cited authors)

citation count

complete list of authors

publication date

publisher

published in

Research

keywords

Identity

PubMed Central ID

Digital Object Identifier (DOI)

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