Sub-micron fracture mechanism in silica-based glass activated by permanent densification from high-strain loading

Wereszczak, Andrew A.; Waters, Shirley B.; Parten, Randy J.; Pye, L. David

doi:10.1016/j.jnoncrysol.2016.04.029

Title: Sub-micron fracture mechanism in silica-based glass activated by permanent densification from high-strain loading

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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. Furthermore, 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 thatmore »« less

Authors:

Wereszczak, Andrew A. ^[1]; Waters, Shirley B. ^[1]; Parten, Randy J. ^[1]; Pye, L. David ^[2]

Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)
The New York State College of Ceramics at Alfred Univ., Little Falls, NY (United States)

Publication Date:: Tue Apr 26 00:00:00 EDT 2016

Research Org.:: Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)

Sponsoring Org.:: USDOE

OSTI Identifier:: 1250403

Alternate Identifier(s):: OSTI ID: 1467160

Grant/Contract Number:: AC05-00OR22725; NFE-10-03121

Resource Type:: Accepted Manuscript

Journal Name:: Journal of Non-Crystalline Solids

Additional Journal Information:: Journal Volume: 443; Journal ID: ISSN 0022-3093

Publisher:: Elsevier

Country of Publication:: United States

Language:: English

Subject:: 36 MATERIALS SCIENCE; silica-based glasses; high-strain-energy fracture; densification; fragmentation; microkernels

Citation Formats


                    Wereszczak, Andrew A., Waters, Shirley B., Parten, Randy J., and Pye, L. David. Sub-micron fracture mechanism in silica-based glass activated by permanent densification from high-strain loading.  United States: N. p., 2016. 
Web.  doi:10.1016/j.jnoncrysol.2016.04.029.

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                    Wereszczak, Andrew A., Waters, Shirley B., Parten, Randy J., & Pye, L. David. Sub-micron fracture mechanism in silica-based glass activated by permanent densification from high-strain loading.  United States.  https://doi.org/10.1016/j.jnoncrysol.2016.04.029

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                    Wereszczak, Andrew A., Waters, Shirley B., Parten, Randy J., and Pye, L. David. Tue .  
"Sub-micron fracture mechanism in silica-based glass activated by permanent densification from high-strain loading".  United States.  https://doi.org/10.1016/j.jnoncrysol.2016.04.029.  https://www.osti.gov/servlets/purl/1250403.

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@article{osti_1250403,

  title        = {Sub-micron fracture mechanism in silica-based glass activated by permanent densification from high-strain loading},

  author       = {Wereszczak, Andrew A. and Waters, Shirley B. and Parten, Randy J. and Pye, L. David},

  abstractNote = {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. Furthermore, 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.},

  doi          = {10.1016/j.jnoncrysol.2016.04.029},

  journal      = {Journal of Non-Crystalline Solids},

  number       = ,

  volume       = 443,

  place        = {United States},

  year         = {Tue Apr 26 00:00:00 EDT 2016},

  month        = {Tue Apr 26 00:00:00 EDT 2016}

}

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