TY - JOUR
T1 - Molecular-level computational investigation of shock-wave mitigation capability of polyurea
AU - Grujicic, M.
AU - Yavari, R.
AU - Snipes, J. S.
AU - Ramaswami, S.
AU - Runt, J.
AU - Tarter, J.
AU - Dillon, G.
N1 - Funding Information:
Acknowledgements The material presented in this paper is based on work supported by the Office of Naval Research (ONR) research contract entitled ‘‘Elastomeric Polymer-By-Design to Protect the Warfighter Against Traumatic Brain Injury by Diverting the Blast Induced Shock Waves from the Head’’, Contract Number 4036-CU-ONR-1125 as funded through the Pennsylvania State University, the Army Research Office (ARO) research contract entitled ‘‘Multilength Scale Material Model Development for Armor-grade Composites’’, Contract Number W911NF-09-1-0513, and the Army Research Laboratory (ARL) research contract entitled ‘‘Computational Analysis and Modeling of Various Phenomena Accompanying Detonation Explosives Shallow-Buried in Soil’’ Contract Number W911NF-06-2-0042. The authors are indebted to Drs. Roshdy Barsoum of ONR and Larry C. Russell, Jr. of ARO for their continuing support and interest in this study.
PY - 2012/12
Y1 - 2012/12
N2 - Various static and (equilibrium and non-equilibrium) dynamic molecular-level computational methods and tools are utilized in order to investigate the basic shock-wave physics and shock-wave material interactions in polyurea (α nano-phase segregated elastomeric co-polymer). The main goal of this investigation was to establish relationships between the nano-segregated polyurea microstructure (consisting of rod-shaped, discrete, so-called "hard domains" embedded into a highly compliant, so-called soft matrix) and the experimentally established superior capability of this material to disperse and attenuate resident shock waves (e.g., those generated as a result of blast-wave impact). By analyzing molecularlevel interactions of the shock waves with polyurea, an attempt was made to identify and quantify main phenomena and viscous/inelastic deformation and microstructurealtering processes taking place at the shock front, which are most likely responsible for the superior shock-mitigation behavior of polyurea. Direct molecular-level simulations of shock-wave generation and propagation in the " strongshock" regime are utilized in order to construct the appropriate shock-Hugoniot relations (relations which are used in the construction of the associated continuum-level material models). Extension of these relations into the "weak-shock" regime of interest from the traumatic brain injury prevention point of view is also discussed.
AB - Various static and (equilibrium and non-equilibrium) dynamic molecular-level computational methods and tools are utilized in order to investigate the basic shock-wave physics and shock-wave material interactions in polyurea (α nano-phase segregated elastomeric co-polymer). The main goal of this investigation was to establish relationships between the nano-segregated polyurea microstructure (consisting of rod-shaped, discrete, so-called "hard domains" embedded into a highly compliant, so-called soft matrix) and the experimentally established superior capability of this material to disperse and attenuate resident shock waves (e.g., those generated as a result of blast-wave impact). By analyzing molecularlevel interactions of the shock waves with polyurea, an attempt was made to identify and quantify main phenomena and viscous/inelastic deformation and microstructurealtering processes taking place at the shock front, which are most likely responsible for the superior shock-mitigation behavior of polyurea. Direct molecular-level simulations of shock-wave generation and propagation in the " strongshock" regime are utilized in order to construct the appropriate shock-Hugoniot relations (relations which are used in the construction of the associated continuum-level material models). Extension of these relations into the "weak-shock" regime of interest from the traumatic brain injury prevention point of view is also discussed.
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U2 - 10.1007/s10853-012-6716-4
DO - 10.1007/s10853-012-6716-4
M3 - Article
AN - SCOPUS:84868349077
SN - 0022-2461
VL - 47
SP - 8197
EP - 8215
JO - Journal of Materials Science
JF - Journal of Materials Science
IS - 23
ER -