Direct measurement of bending stiffness and estimation of Young's modulus of vertically aligned carbon nanofibers
Journal article, 2013
The bending stiffness of individual, as-grown, vertically aligned carbon nanofibers was measured using a custom-built atomic force microscope placed inside a scanning electron microscope. The internal structure of the nanofiber was best modeled as dual-phase, composed of an inner graphitic core covered with a tapered amorphous carbon shell. It was found that the fibers have a relatively low bending stiffness, with Young's modulus values of about 10 GPa for the inner core and 65 GPa for the outer shell. The low Young's modulus of the inner core is attributed to a non-zero angle between the graphitic sheets and the nanofiber axis. The weak shear modulus between graphitic sheets thereby dominates the mechanical behaviour of the fibers.
elastic-modulus
nanotubes
switches
Author
Farzan Alavian Ghavanini
Chalmers, Applied Physics, Electronics Material and Systems
H. Jackman
Karlstad University
Per Lundgren
Chalmers, Applied Physics, Electronics Material and Systems
Krister Svensson
Karlstad University
Peter Enoksson
Chalmers, Applied Physics, Electronics Material and Systems
Journal of Applied Physics
0021-8979 (ISSN) 1089-7550 (eISSN)
Vol. 113 19 194308Areas of Advance
Nanoscience and Nanotechnology
Transport
Production
Roots
Basic sciences
Subject Categories
Electrical Engineering, Electronic Engineering, Information Engineering
Infrastructure
Nanofabrication Laboratory
DOI
10.1063/1.4803853