Design and evaluation of a nanoscale differential tensile test device for nanofibers

Dennis Edmondson; Narayan Bhattarai; Soumen Jana; Abraham Kim; Miqin Zhang

doi:10.1063/1.3095439

Design and evaluation of a nanoscale differential tensile test device for nanofibers

Dennis Edmondson, Narayan Bhattarai, Soumen Jana, Abraham Kim, Miqin Zhang

Cardiovascular Medicine

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

9 Scopus citations

Abstract

The development of nanofibers could open new avenues in fundamental research and novel applications. Tensile properties of these nanofibers are a good indicator of their overall mechanical response. However, accurate measurements of tensile properties at the micro- and nanoscales remain a challenge. Here we report a simple but highly efficient differential nanoscale tensile test device constructed from off the shelf state-of-the-art components. The unique feature of this device is that it can measure the applied load and specimen's deformation in the nanonewton and nanometer scales, respectively. First experimental results on electrospun nanofibers are reported.

Original language	English (US)
Article number	103101
Journal	Applied Physics Letters
Volume	94
Issue number	10
DOIs	https://doi.org/10.1063/1.3095439
State	Published - 2009

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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10.1063/1.3095439

Cite this

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title = "Design and evaluation of a nanoscale differential tensile test device for nanofibers",

abstract = "The development of nanofibers could open new avenues in fundamental research and novel applications. Tensile properties of these nanofibers are a good indicator of their overall mechanical response. However, accurate measurements of tensile properties at the micro- and nanoscales remain a challenge. Here we report a simple but highly efficient differential nanoscale tensile test device constructed from off the shelf state-of-the-art components. The unique feature of this device is that it can measure the applied load and specimen's deformation in the nanonewton and nanometer scales, respectively. First experimental results on electrospun nanofibers are reported.",

author = "Dennis Edmondson and Narayan Bhattarai and Soumen Jana and Abraham Kim and Miqin Zhang",

note = "Funding Information: Thanks are due to Kevin Soderland, Eamon McQuaide, and Bill Kuykendal from University of Washington, Department of Mechanical Engineering for their contributions to fabricate the device. This work was supported in part by the University of Washington Engineered Biomaterials Research Center (NSF-EEC Grant No. 9529161). We also acknowledge the University of Washington NanoTech user facility for SEM imaging.",

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doi = "10.1063/1.3095439",

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AU - Edmondson, Dennis

AU - Bhattarai, Narayan

AU - Jana, Soumen

AU - Kim, Abraham

AU - Zhang, Miqin

N1 - Funding Information: Thanks are due to Kevin Soderland, Eamon McQuaide, and Bill Kuykendal from University of Washington, Department of Mechanical Engineering for their contributions to fabricate the device. This work was supported in part by the University of Washington Engineered Biomaterials Research Center (NSF-EEC Grant No. 9529161). We also acknowledge the University of Washington NanoTech user facility for SEM imaging.

PY - 2009

Y1 - 2009

N2 - The development of nanofibers could open new avenues in fundamental research and novel applications. Tensile properties of these nanofibers are a good indicator of their overall mechanical response. However, accurate measurements of tensile properties at the micro- and nanoscales remain a challenge. Here we report a simple but highly efficient differential nanoscale tensile test device constructed from off the shelf state-of-the-art components. The unique feature of this device is that it can measure the applied load and specimen's deformation in the nanonewton and nanometer scales, respectively. First experimental results on electrospun nanofibers are reported.

AB - The development of nanofibers could open new avenues in fundamental research and novel applications. Tensile properties of these nanofibers are a good indicator of their overall mechanical response. However, accurate measurements of tensile properties at the micro- and nanoscales remain a challenge. Here we report a simple but highly efficient differential nanoscale tensile test device constructed from off the shelf state-of-the-art components. The unique feature of this device is that it can measure the applied load and specimen's deformation in the nanonewton and nanometer scales, respectively. First experimental results on electrospun nanofibers are reported.

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Design and evaluation of a nanoscale differential tensile test device for nanofibers

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