Paper Titles

System Fatigue Damage Reliability Assessment of Railway Riveted Bridges
p.173

Fatigue Behavior of RC Slab Retrofitted with Carbon Fiber Mesh after Different Levels of Pre-Damage
p.179

Assessing the Feasibility of Monitoring the Condition of Historic Tapestries Using Engineering Techniques
p.187

Damage Assessment of Beams Using Flexural Wave Reflection Coefficients
p.193

Damage Assessment of Nanostructures
p.199

Damage Detection in an Aluminium Plate with an Active Constrained Layer Damping Treatment
p.205

An Investigation on Damage Detection in Aircrafts Panels Using Nonlinear Time Series Analysis
p.213

Modal-Model Applications for Large Energetic Machines
p.221

Bayesian Approach to Condition Monitoring of PRC Bridges
p.227

HomeKey Engineering MaterialsKey Engineering Materials Vol. 347Damage Assessment of Nanostructures

Damage Assessment of Nanostructures

Article Preview

Abstract:

In this paper the damage assessment of nanostructures is discussed. As an example we assess the damage of nanobeams with non destructive dynamical resonance or destructive tensile tests: a small number of nanocracks, i.e., ~10, with length of ~1nm, is accordingly estimated.

You might also be interested in these eBooks

Damage Assessment of Structures VII

Info:

Periodical:

Key Engineering Materials (Volume 347)

Pages:

199-204

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.347.199

Citation:

Cite this paper

Online since:

September 2007

Authors:

Nicola Maria Pugno

Keywords:

Damage Assessment, Nanostructure, Nanowire, Quantized Fracture, Resonance, Weibull

Export:

RIS, BibTeX

Price:

Permissions:

Request Permissions

[1] P. Poncharal, Z.L. Wang, D. Ugarte and W.A. De Heer: Science Vol. 283 (1999), p.1513.

[2] Z.L. Wang, P. Poncharal and W.A. de Heer: Pure and Applied Chemistry Vol. 72 (2000), p.209.

[3] X.D. Bai, P.X. Gao, Z.L. Wang and E.G. Wang: Applied Physics Letters Vol. 82 (2003), p.4806.

[4] D.A. Dikin, X. Chen, W. Ding, G. Wagmer and R.S. Ruoff: Journal of Applied Physics Vol. 93 (2003), p.226.

[5] M.F. Yu, O. Lourie, M.J. Dyer, K. Moloni, T.F. Kelly and R.S. Ruoff: Science Vol. 287 (2000), p.637.

[6] X.Q. Chen, S.L. Zhang, G.J. Wagner, W. Ding and R.S. Ruoff: Journal of Applied Physics Vol. 95 (2004), p.4823.

[7] C.J. Otten, O. Lourie, M.F. Yu, J.M. Cowley, M.J. Dyer, R.S. Ruoff and W.E. Buhro: Journal of the American Chemical Society, Vol. 124 (2002), p.4564.

DOI: 10.1021/ja017817s

[8] W. Ding, L. Calabri, X. Chen, K.M. Kohlhaas and R.S. Ruoff: Composite Science and Technology Vol. 66 (2006), p.1099.

[9] L. Calabri, N. Pugno, W. Ding and R. Ruoff: J. of Physics - Condensed Matter Vol. 18 (2006), p. S2175.

DOI: 10.1088/0953-8984/18/33/s33

[10] W. Ding, D.A. Dikin, X. Chen, X. Wang, X. Li, R.D. Piner, R.S. Ruoff and E. Zussman: Journal of Applied Physics Vol. 98 (2005), p.014905.

DOI: 10.1063/1.1940138

[11] N. Pugno, R. Ruotolo and C. Surace: J. of Sound and Vibration Vol. 235 (2000), p.749.

[12] A. Carpinteri and N. Pugno: J. of Applied Mechanics Vol. 72 (2005), p.511.

[13] A. Carpinteri and N. Pugno: J. of Applied Mechanics Vol. 72 (2005), p.519.

[14] P. J. Gudmunson: J. Mech. Phys. Solids Vol. 31 (1983), p.329.

[15] N. Pugno and R. Ruoff: Philosophical Magazine Vol. 84 (2004), p.2829.

[16] N. Pugno: Int. J. of Fracture Vol. 141 (2006), p.311.

[17] N. Pugno: J. of Physics - Condensed Matter Vol. 18 (2006), p. S1971.

[18] N. Pugno: Int. J. of Fracture Vol. 140 (2006), p.158.

[19] N. Pugno and R. Ruoff: J. Appl. Physics Vol. 99 (2006), p.024301/1.

[20] W. Weibull: J. Appl. Mech. Vol. 18 (1951), p.293.

[21] J.R. Rice and N. Levy: J. of Appl. Mech. Vol. 39 (1972), p.185.