Virtual experiments on complex materials

Gary W. Delaney; Shio Inagaki; T. Di Matteo; Tomaso Aste

doi:10.1117/12.759412

Virtual experiments on complex materials

Gary W. Delaney, Shio Inagaki, T. Di Matteo, Tomaso Aste

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

3 Citations (Scopus)

Abstract

We investigate complex materials by performing "Virtual Experiments" starting from three-dimensional images of grain packs obtained by X-ray CT imaging [1]. We apply this technique to granular materials by reconstructing a numerical samples of ideal spherical beads with desired (and tunable) properties. The resulting "virtual packing" has a structure that is almost identical to the experimental one. However, from such a digital duplicate we can calculate several static and dynamical properties (e.g. the force network, avalanche precursors, stress paths, stability, fragility, etc.) which are otherwise not directly accessible from experiments. Our simulation code handles three-dimensional spherical grains and it takes into account repulsive elastic normal forces, frictional tangential forces, viscous damping and gravity. The system can be both simulated within a vessel or with periodic boundary conditions.

Original language	English
Title of host publication	Complex Systems II
DOIs	https://doi.org/10.1117/12.759412
Publication status	Published - 2008
Event	Complex Systems II - Canberra, Australia Duration: 5 Dec 2007 → 7 Dec 2007

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	6802
ISSN (Print)	0277-786X

Conference

Conference	Complex Systems II
Country/Territory	Australia
City	Canberra
Period	5/12/07 → 7/12/07

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10.1117/12.759412

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@inproceedings{82a3431c63d44011a4023b5880200eda,

title = "Virtual experiments on complex materials",

abstract = "We investigate complex materials by performing {"}Virtual Experiments{"} starting from three-dimensional images of grain packs obtained by X-ray CT imaging [1]. We apply this technique to granular materials by reconstructing a numerical samples of ideal spherical beads with desired (and tunable) properties. The resulting {"}virtual packing{"} has a structure that is almost identical to the experimental one. However, from such a digital duplicate we can calculate several static and dynamical properties (e.g. the force network, avalanche precursors, stress paths, stability, fragility, etc.) which are otherwise not directly accessible from experiments. Our simulation code handles three-dimensional spherical grains and it takes into account repulsive elastic normal forces, frictional tangential forces, viscous damping and gravity. The system can be both simulated within a vessel or with periodic boundary conditions.",

author = "Delaney, {Gary W.} and Shio Inagaki and {Di Matteo}, T. and Tomaso Aste",

year = "2008",

doi = "10.1117/12.759412",

language = "English",

isbn = "9780819469731",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

booktitle = "Complex Systems II",

note = "Complex Systems II ; Conference date: 05-12-2007 Through 07-12-2007",

}

TY - GEN

T1 - Virtual experiments on complex materials

AU - Delaney, Gary W.

AU - Inagaki, Shio

AU - Di Matteo, T.

AU - Aste, Tomaso

PY - 2008

Y1 - 2008

N2 - We investigate complex materials by performing "Virtual Experiments" starting from three-dimensional images of grain packs obtained by X-ray CT imaging [1]. We apply this technique to granular materials by reconstructing a numerical samples of ideal spherical beads with desired (and tunable) properties. The resulting "virtual packing" has a structure that is almost identical to the experimental one. However, from such a digital duplicate we can calculate several static and dynamical properties (e.g. the force network, avalanche precursors, stress paths, stability, fragility, etc.) which are otherwise not directly accessible from experiments. Our simulation code handles three-dimensional spherical grains and it takes into account repulsive elastic normal forces, frictional tangential forces, viscous damping and gravity. The system can be both simulated within a vessel or with periodic boundary conditions.

AB - We investigate complex materials by performing "Virtual Experiments" starting from three-dimensional images of grain packs obtained by X-ray CT imaging [1]. We apply this technique to granular materials by reconstructing a numerical samples of ideal spherical beads with desired (and tunable) properties. The resulting "virtual packing" has a structure that is almost identical to the experimental one. However, from such a digital duplicate we can calculate several static and dynamical properties (e.g. the force network, avalanche precursors, stress paths, stability, fragility, etc.) which are otherwise not directly accessible from experiments. Our simulation code handles three-dimensional spherical grains and it takes into account repulsive elastic normal forces, frictional tangential forces, viscous damping and gravity. The system can be both simulated within a vessel or with periodic boundary conditions.

UR - http://www.scopus.com/inward/record.url?scp=41149163156&partnerID=8YFLogxK

U2 - 10.1117/12.759412

DO - 10.1117/12.759412

M3 - Conference contribution

SN - 9780819469731

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Complex Systems II

T2 - Complex Systems II

Y2 - 5 December 2007 through 7 December 2007

ER -

Virtual experiments on complex materials

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