Abstract
Several silica-based glasses were fractured at high strain energy via drop-weight testing on small specimens. A cylindrical specimen geometry was chosen to promote initially simple, axisymmetric, and uniform compressive loading. The imposed uniaxial compressive strain at impact was sufficiently high to qualitatively cause permanent densification. Produced fragments were collected for postmortem and a fraction of them, for all the silica-based glasses, consistently had distinct sub-micron-sized fractures (~ 300-1000 nm), designated here as "microkernels", on their surfaces. They would most often appear as a sub-micron pore on the fragment - apparently if the microkernel had popped out as a consequence of the local crack plane running through it, tensile-strain release, and the associated formation of the fragment it was on. No fractographic evidence was found to show the microkernels were associated with local failure initiation. However, their positioning and habit sometimes suggested they were associated with localized crack branching and that they could have influenced secondary fracturing that occurred during overall crushing and comminution and associated fragment size and shape creation. The size range of these microkernels is much too small to affect structural flexure strength of these glasses for most applications but are of a size and concentration that may affect their ballistic, shock, crush, and comminution responses when permanent densification is concomitantly occurring.
Original language | English |
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Pages (from-to) | 172-183 |
Number of pages | 12 |
Journal | Journal of Non-Crystalline Solids |
Volume | 443 |
DOIs | |
State | Published - Jul 1 2016 |
Funding
The authors thank T. Talladay, A. Dolan, and D. Templeton (retired) of the US Army Tank-Automotive Research, Development and Engineering Center (TARDEC) , W. Chen of Purdue University , and P. Patel of the US Army Research Laboratory (USARL) for their support of this work, and the latter for also supplying some of the materials for this testing. Gratitude is extended to P. Patel and J. Swab of USARL, T. Holmquist of SWRI, G. Quinn (retired) of NIST, M. Davis of Schott Glass, N. Borelli and T. Seward (retired) of Corning Glass, A. Moreira Dos Santos, M. Ferber (deceased), and P. Becher (retired) of ORNL, and D. Grady of ARA for their helpful insights, and ORNL's E. Lara-Curzio, H. Wang, and J. -A. Wang for their reviews.
Funders | Funder number |
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US Army Tank-Automotive Research, Development and Engineering Center | |
Purdue University | |
Army Research Laboratory | |
Tank Automotive Research, Development and Engineering Center |
Keywords
- Densification
- Fragmentation
- High-strain-energy fracture
- Microkernels
- Silica-based glasses