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Journal of Materials Engineering and Performance

Erschienen in:

01.12.2015

The Effect of High-Pressure Devitrification and Densification on Ballistic-Penetration Resistance of Fused Silica

verfasst von: M. Grujicic, V. Avuthu, J. S. Snipes, S. Ramaswami, R. Galgalikar

Erschienen in: Journal of Materials Engineering and Performance | Ausgabe 12/2015

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Abstract

Recent experimental and molecular-level computational analyses have indicated that fused silica, when subjected to pressures of several tens of GPa, can experience irreversible devitrification and densification. Such changes in the fused-silica molecular-level structure are associated with absorption and/or dissipation of the strain energy acquired by fused silica during high-pressure compression. This finding may have important practical consequences in applications for fused silica such as windshields and windows of military vehicles, portholes in ships, ground vehicles, spacecraft, etc. In the present work, our prior molecular-level computational results pertaining to the response of fused silica to high pressures (and shear stresses) are used to enrich a continuum-type constitutive model (that is, the so-called Johnson-Holmquist-2, JH2, model) for this material. Since the aforementioned devitrification and permanent densification processes modify the response of fused silica to the pressure as well as to the deviatoric part of the stress, changes had to be made in both the JH2 equation of state and the strength model. To assess the potential improvements in respect to the ballistic-penetration resistance of this material brought about by the fused-silica devitrification and permanent densification processes, a series of transient non-linear dynamics finite-element analyses of the transverse impact of a fused-silica test plate with a solid right-circular cylindrical steel projectile were conducted. The results obtained revealed that, provided the projectile incident velocity and, hence, the attendant pressure, is sufficiently high, fused silica can undergo impact-induced devitrification, which improves its ballistic-penetration resistance.

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E. Strassburger, P. Patel, W. McCauley, and D. W. Templeton, Visualization of Wave Propagation and Impact Damage in a Polycrystalline Transparent Ceramic-AlON, Proceedings of the 22nd International Symposium on Ballistics, November 2005, Vancouver, Canada.

AMPTIAC Quarterly, Army Materials Research: Transforming Land Combat Through New Technologies, 2004, 8(4).

E. Strassburger, P. Patel, J.W. McCauley, C. Kovalchick, K.T. Ramesh, and D.W. Templeton, High-Speed transmission Shadowgraphic and Dynamic Photoelasticity Study of Stress Wave and Impact Damage Propagation in Transparent Materials and Laminates Using The Edge-on Impact Method, Proceedings of the 23rd International Symposium on Ballistics, Spain, April 2007.

D.Z. Sun, F. Andreiux, and A. Ockewitz, Modeling of the Failure Behavior of Windscreens and Component Tests, 4th LS-DYNA Users’ Conference, Bamberg, Germany, 2005

W.D. Kingery, H.K. Bowen, and D.R. Uhlmann, Introduction to Ceramics, 2nd ed., Wiley, New York, 1976, p 91–124

M. Grujicic, W.C. Bell, B. Pandurangan, B.A. Cheeseman, C. Fountzoulas, P. Patel, D.W. Templeton, and K.D. Bishnoi, The Effect of High-pressure Densification on Ballistic-penetration Resistance of Soda-lime Glass, J. Mater.: Design Appl., 2011, 225, p 298–315

C.S. Alexander, L.C. Chhabildas, W.D. Reinhart, and D.W. Templeton, Changes to the shock response of quartz due to glass modification, Int. J. Impact Eng., 2008, 35, p 1376–1385CrossRef

M. Grujicic, B. Pandurangan, N. Coutris, B.A. Cheeseman, C. Fountzoulas, P. Patel, and E. Strassburger, A Ballistic Material Model for Starphire^®, A Soda-Lime Transparent Armor Glass, Mater. Sci. Eng. A, 2008, 492, p 397–411CrossRef

M. Grujicic, B. Pandurangan, W.C. Bell, N. Coutris, B.A. Cheeseman, C. Fountzoulas, and P. Patel, An Improved Mechanical Material Model for Ballistic Soda-Lime Glass, J. Mater. Eng. Perform., 2009, 18, p 1012–1028CrossRef

10.

M. Grujicic, B. Pandurangan, N. Coutris, B.A. Cheeseman, C. Fountzoulas, and P. Patel, A Simple Ballistic Material Model for Soda-Lime Glass, Int. J. Impact Eng., 2009, 36, p 386–401CrossRef

11.

M. Grujicic, W.C. Bell, P.S. Glomski, B. Pandurangan, B.A. Cheeseman, C. Fountzoulas, P. Patel, D.W. Templeton, and K.D. Bishnoi, Multi-Length Scale Modeling of High-Pressure Induced Phase Transformations in Soda-lime Glass, J. Mater. Eng. Perform., 2011, 20, p 1144–1156CrossRef

12.

M. Grujicic, W.C. Bell, B. Pandurangan, B.A. Cheeseman, P. Patel, and G.A. Gazonas, Inclusion of Material Nonlinearity and Inelasticity into a Continuum-Level Material Model for Soda-Lime Glass, Mater. Des., 2012, 35, p 144–155CrossRef

13.

M. Grujicic, W.C. Bell, B. Pandurangan, B.A. Cheeseman, P. Patel, and P.G. Dehmer, Effect of the Tin- vs. Air-Side Plate-Glass Orientation on the Impact Response and Penetration Resistance of a Laminated Transparent-Armor Structure, J. Mater.: Design Appl., 2012, 226, p 119–143

14.

M. Grujicic, B. Pandurangan, Z. Zhang, W.C. Bell, G.A. Gazonas, P. Patel, and B.A. Cheeseman, Molecular-Level Analysis of Shock-Wave Physics and Derivation of the Hugoniot Relations for Fused Silica, J. Mater. Eng. Perform., 2012, 21, p 823–836

15.

M. Grujicic, W.C. Bell, B. Pandurangan, B.A. Cheeseman, C. Fountzoulas, and P. Patel, Molecular-Level Simulations of Shock Generation and Propagation in Soda-Lime Glass, J. Mater. Eng. Perform., 2012, 21, p 1580–1590CrossRef

16.

M. Grujicic, J. S. Snipes, S. Ramaswami, R. Yavari, and R.S. Barsoum, All-Atom Molecular-Level Analysis of the Ballistic-Impact-Induced Densification and Devitrification of Fused Silica, J. Nanomater., 2015, Article ID 650625, 2015. doi:10.1155/2015/650625.

17.

R. Chakraborty, A. Dey, and A.K. Mukhopadhyay, Loading Rate Effect on Nanohardness of Soda-Lime-Silica Glass, Metall. Mater. Trans. A, 2010, 41, p 1301–1312CrossRef

18.

O. Tschauner, S.-N. Luo, P.D. Asimow, and T.J. Ahrens, Recovery of Stishovite-Structure at Ambient Conditions Out of Shock-Generated Amorphous Silica, Am. Mineral., 2006, 91, p 1857–1862CrossRef

19.

A. Salleo, S.T. Taylor, M.C. Martin, W.R. Panero, R. Jeanloz, T. Sands, and F.Y. Génin, Laser-Driven Formation of a High-Pressure Phase in Amorphous Silica, Nat. Mater., 2003, 2, p 796–800CrossRef

20.

B. Mantisi, A. Tanguy, G. Kermouche, and E. Barthel, Atomistic Response of a Model Silica Glass Under Shear and Pressure, Eur. Phys. J. B, 2012, 85, p 304–316CrossRef

21.

A. Kubota, M.-J. Caturla, L. Davila, J. Stolken, B. Sadigh, A. Quong, A. Rubenchik, and M.D. Feit, Atomistic response of a model silica glass under shear and pressure, Laser-Induced Damage in Optical Materials 2001, Proceedings of SPIE, G.J. Exarhos, A.H. Guenther, K.L. Lewis, M.J. Soileau, C.J. Stolz, Ed., 4679, 2002, pp. 108–116

22.

G. R. Johnson, and T. J. Holmquist, An improved computational constitutive model for brittle materials, High-Pressure Science and Technology, 1993: Proceedings of the joint International Association for Research and Advancement of High Pressure Science, June 28–July 2, 1993, pp. 981–991.

23.

T.J. Holmquist, D.W. Templeton, and K.D. Bishnoi, Constitutive Modeling of Aluminum Nitride for Large Strain High-Strain Rate, and High-Pressure Applications, Int. J. Impact Eng., 2001, 25, p 211–231CrossRef

24.

G.R. Johnson and T.J. Holmquist, An Improved Computational Constitutive Model for Brittle Materials, High Pressure Science and Technology, 1993, AIP, New York, 1994

25.

ABAQUS Version 6.14, User Documentation, Dassault Systèmes, 2014.

26.

M. Grujicic, B. Pandurangan, U. Zecevic, K.L. Koudela, and B.A. Cheeseman, Ballistic Performance of Alumina/S-2 Glass-Reinforced Polymer-Matrix Composite Hybrid Lightweight Armor Against Armor Piercing (AP) and Non-AP Projectiles, Multidiscip. Model. Mater. Struct., 2007, 3, p 287–312CrossRef

27.

M. Grujicic, J.S. Snipes, S. Ramaswami, R. Yavari, and R.S. Barsoum, All-Atom Molecular-Level Analysis of the Ballistic-Impact-Induced Densification and Devitrification of Fused Silica, J. Mater. Eng. Perform., 2015, 24(8), p 2970–2983CrossRef

28.

M. Grujicic, V. Chenna, R. Galgalikar, J.S. Snipes, S. Ramaswami, and R. Yavari, Wind-Turbine Gear-Box Roller-Bearing Premature-Failure caused by Grain-Boundary Hydrogen Embrittlement, J. Mater. Eng. Perform., 2014, 23, p 3984–4001CrossRef

29.

M. Grujicic, S. Ramaswami, R. Yavari, R. Galgalikar, V. Chenna, and J.S. Snipes, Multi-Physics Computational Analysis of White-Etch Cracking Failure Mode in Wind-Turbine Gear-Box Bearings, J. Mater.: Design Appl., 2014. doi:10.1177/1464420714544803.

30.

M. Grujicic, V. Chenna, R. Galgalikar, J.S. Snipes, S. Ramaswami, and R. Yavari, Computational Analysis of Gear-Box Roller-Bearing White-Etch Cracking: A Multi-Physics Approach, Int. J. Struct. Integrity, 2014, 5(4), p 290–327CrossRef

31.

M. Grujicic, V. Chenna, R. Yavari, R. Galgalikar, J.S. Snipes, and S. Ramaswami, Multi-Length Scale Computational Analysis of Roller-Bearing Premature Failure in Horizontal-Axis Wind-Turbine Gear-Boxes, Int. J. Struct. Integrity, 2015, 5(1), p 40–72CrossRef

Titel: The Effect of High-Pressure Devitrification and Densification on Ballistic-Penetration Resistance of Fused Silica
verfasst von: M. Grujicic
V. Avuthu
J. S. Snipes
S. Ramaswami
R. Galgalikar
Publikationsdatum: 01.12.2015
Verlag: Springer US
Erschienen in: Journal of Materials Engineering and Performance / Ausgabe 12/2015
Print ISSN: 1059-9495
Elektronische ISSN: 1544-1024
DOI: https://doi.org/10.1007/s11665-015-1775-8

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