Nanoscale Molecular Dynamics Simulaton of Shock Compression of Silicon
Abstract
We report results of molecular dynamics simulation of shock wave propagation in silicon in [100], [110], and [111] directions obtained using a classical environment-dependent interatomic potential (EDIP). Several regimes of materials response are classified as a function of shock wave intensity using the calculated shock Hugoniot. Shock wave structure in [100] and [111] directions exhibit usual evolution as a function of piston velocity. At piston velocities 1.25< vp < 2.75 km/s the shock wave consists of a fast elastic precursor followed by a slower plastic front. At larger piston velocities the single overdriven plastic wave propagates through the crystal causing amorphization of Si. However, the [110] shock wave exhibits an anomalous materials response at intermediate piston velocities around vp ~= 1.75 km/s which is characterized by the absence of plastic deformations.
Additional Information
© 2006 American Institute of Physics. The work at USF is supported by NSF-NIRT (ECS-0404137) and ARO-MURI (W901 1NF-05-1-0266). Funding at Caltech was provided by ONR and ARO-MURI. CTW is supported by ONR directly and through Naval Research Laboratory.Attached Files
Published - OLEaipcp06c.pdf
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Additional details
- Eprint ID
- 5141
- Resolver ID
- CaltechAUTHORS:OLEaipcp06c
- ECS-0404137
- NSF
- W901 1NF-05-1-0266
- Army Research Office (ARO)
- Office of Naval Research (ONR)
- Naval Research Laboratory
- Created
-
2006-10-03Created from EPrint's datestamp field
- Updated
-
2023-06-01Created from EPrint's last_modified field
- Series Name
- AIP Conference Proceedings
- Series Volume or Issue Number
- 845