<i>In situ</i>
 X-Ray Diffraction of Shock-Compressed Fused Silica

Tracy, S. J.; Turneaure, Stefan J.; Duffy, Thomas S.

doi:10.1103/physrevlett.120.135702

Cited by 68 publications

(44 citation statements)

References 53 publications

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“…The 44-to 72-GPa stress range to which fused silica was shock-compressed in this study is above the stress at which fused silica is known to transform to stishovite (36 GPa; Tracy et al, 2018). Our measured longitudinal sound velocities range from 11.7-12.3 km/s at 44 GPa to 9.8-10.3 km/s at 72 GPa ( Figure 3).…”

Section: Discussionmentioning

confidence: 55%

“…The most likely explanation is that shock-synthesized stishovite is partially melting over this stress range. In the XRD experiments of Tracy et al (2018) up to 63 GPa, there is no clear evidence for the presence of melt, but small amounts of liquid would likely not be detected in such experiments. This leads to an eventual complete loss of shear stiffness and complete melting at 72 GPa, as discussed above.…”

Section: Discussionmentioning

confidence: 98%

“…The results from this and previous studies are compared to the longitudinal and bulk (C B ) sound speeds in stishovite and CaCl 2 -type SiO 2 at high temperature and pressure from theoretical calculations(Yang & Wu, 2014). The approximate lower limit of stishovite formation on the Hugoniot determined byTracy et al (2018) is shown by the vertical black line. The approximate lower limit of stishovite formation on the Hugoniot determined byTracy et al (2018) is shown by the vertical black line.…”

mentioning

confidence: 89%

“…Both quartz and fused silica transform to dense, stiffer phases at high stress on the Hugoniot. In the gas-gun experiments of Tracy et al (2018), fused silica remained amorphous before transforming to untextured, polycrystalline stishovite with no evidence of preferred orientation above 34 GPa under shock compression. In the gas-gun experiments of Tracy et al (2018), fused silica remained amorphous before transforming to untextured, polycrystalline stishovite with no evidence of preferred orientation above 34 GPa under shock compression.…”

Section: Introductionmentioning

confidence: 98%

“…Eulerian longitudinal sound speed (C E ) measured in shock-compressed fused silica. The highest single-shock (SS) and double-shock (DS) stress investigated by in situ XRD(Tracy et al, 2018) are indicated. The highest single-shock (SS) and double-shock (DS) stress investigated by in situ XRD(Tracy et al, 2018) are indicated.…”

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confidence: 99%

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Sound Velocities in Shock‐Synthesized Stishovite to 72 GPa

Berryman

Winey

Gupta

et al. 2019

Geophysical Research Letters

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Stishovite (rutile-type SiO 2 ) is the archetype of dense silicates and may occur in postgarnet eclogitic rocks at lower-mantle conditions. Sound velocities in stishovite are fundamental to understanding its mechanical and thermodynamic behavior at high pressure and temperature. Here, we use plate-impact experiments combined with velocity interferometry to determine the stress, density, and longitudinal sound speed in stishovite formed during shock compression of fused silica at 44 GPa and above. The measured sound speeds range from 12.3(8) km/s at 43.8(8) GPa to 9.8(4) km/s at 72.7(11) GPa. The decrease observed at 64 GPa reflects a decrease in the shear modulus of stishovite, likely due to the onset of melting. By 72 GPa, the measured sound speed agrees with the theoretical bulk sound speed indicating loss of all shear stiffness due to complete melting. Our sound velocity results provide direct evidence for shock-induced melting, in agreement with previous pyrometry data.

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Section: Discussionmentioning

confidence: 55%

Section: Discussionmentioning

confidence: 98%

mentioning

confidence: 89%

Section: Introductionmentioning

confidence: 98%

mentioning

confidence: 99%

See 3 more Smart Citations

Sound Velocities in Shock‐Synthesized Stishovite to 72 GPa

Berryman

Winey

Gupta

et al. 2019

Geophysical Research Letters

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The Crystallization of Disordered Materials under Shock Is Governed by Their Network Topology

et al. 2023

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When the shock load is applied, materials experience incredibly high temperature and pressure conditions on picosecond timescales, usually accompanied by remarkable physical or chemical phenomena. Understanding the underlying physics that governs the kinetics of shocked materials is of great importance for both physics and materials science. Here, combining experiment and large‐scale molecular dynamics simulation, the ultrafast nanoscale crystal nucleation process in shocked soda‐lime silicate glass is investigated. By adopting topological constraints theory, this study finds that the propensity of nucleation is governed by the connectivity of the atomic network. The densification of local networks, which appears once the crystal starts to grow, results in the underconstrained shell around the crystal and prevents further crystallization. These results shed light on the nanoscale crystallization mechanism of shocked materials from the viewpoint of topological constraint theory.

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