Structural transformations in laser shock-loaded quartz

Rességuier, T. de; Berterretche, P.; Hallouin, M.; Petitet, J. P.

doi:10.1063/1.1589602

Cited by 17 publications

(25 citation statements)

References 25 publications

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“…In recent papers, we have investigated the structural effects of laser-driven shocks on quartz [3,4]. Here, we report additional observations concerning spall damage in laser shock-loaded quartz samples, we explain the results in terms of orientated wave propagation due to quartz anisotropic crystalline structure, and we perform three-dimensional (3D) computer simulations to comfort this interpretation.…”

Section: Introductionmentioning

confidence: 56%

“…The angle between the major axis of the ellipsoid and Given the lateral dimensions of the samples, about 15 mm, this 'elliptical' damage observed at the back of all thick quartz samples shocked along the x-axis cannot be attributed to edge effects. It was not observed in laser shock experiments performed on thin quartz samples (less than 1 mm thick) reported elsewhere [3], where the propagation distances were small compared to the diameter of the irradiated spots (typically 3 mm). Thus, it is likely to result from specifically orientated wave propagation in quartz, due to the anisotropic structure of the quartz crystal.…”

Section: Shocked Surface Normal To the X-axis Of The Crystalmentioning

confidence: 63%

“…The gold layer is ablated into a plasma cloud, whose expansion towards the laser source induces a short compressive pulse in the quartz sample, due to recoil action. Previous experiments and laser-matter interaction computations have shown that the corresponding loading pressures, which increase with laser intensity, range from about 12 to 84 GPa [3][4][5][6][7]. Unlike in most laser shock experiments that we reported in the past, the diameter of the irradiated surface is less than the target thickness, so that strains cannot be considered as uniaxial, and 3D effects have to be taken into account to describe stress wave propagation inside the sample.…”

Section: Resultsmentioning

confidence: 80%

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Influence of quartz anisotropy on shock propagation and spall damage

Rességuier¹,

Berterretche²,

Hallouin³

2005

International Journal of Impact Engineering

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Section: Introductionmentioning

confidence: 56%

Section: Shocked Surface Normal To the X-axis Of The Crystalmentioning

confidence: 63%

Section: Resultsmentioning

confidence: 80%

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Influence of quartz anisotropy on shock propagation and spall damage

Rességuier¹,

Berterretche²,

Hallouin³

2005

International Journal of Impact Engineering

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“…Although the examined portion was predominantly quartz, we observed changes in the Raman spectrum, indicating structural disorder characteristic of the onset of a coordination change in silica. Similar effects on the Raman spectrum of quartz had been found in recent laser shock experiments [47] which also indicate the transformation of quartz into a transitional phase observed in powder-gun experiments [48]. We plan to conduct micro-Laue diffraction on laser-shocked quartz crystallites in order to acquire detailed information on intermediate structures, as well as the transformation path from four-to six-fold coordinated silica.…”

Section: Recoverymentioning

confidence: 99%

“…Recovered samples are then post-examined with various analytical FIGURE 10 Ellipsometry signals recorded at the interface of Si (1 0 0) and window [37]: (a) below diamond-bct transition (Trident #14968, P 9 GPa) and (b) around diamond-bct transition (Trident #14969, P 14-17 GPa). techniques to investigate the physical, mechanical, and chemical effects of loading, including metallography [46] and Raman [47], X-ray, and neutron scattering. Although laser shock recovery has been extensively conducted at Trident (e.g., on Al, Cu, Ti, Si, NiTi, NiAl, SiO 2 , MgB 2 , and C), here we only discuss silica and carbon.…”

Section: Recoverymentioning

confidence: 99%

Laser-induced shock waves in condensed matter: some techniques and applications

Luo

Swift

Tierney

et al. 2004

High Pressure Research

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Laser-induced shock waves in condensed matter have important applications in dynamic material studies and high pressure physics. We briefly review some techniques in laser-induced shock waves, including direct laser drive, laser-launched flyer plate, quasi-isentropic loading, point and line imaging velocity interferometry, transient X-ray diffraction, spectroscopy and shock recovery, and their applications to study of equation of state, spallation, and phase transitions.

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Effect of grain size distribution on Raman analyses and the consequences for in situ planetary missions

Foucher

López‐Reyes

Bost

et al. 2013

J Raman Spectroscopy

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Raman spectroscopy can be used for analysing both mineral and organic phases, thus allowing characterisation of the microbial‐scale geological context as well as the search for possible traces of life. This method is therefore very useful for in situ planetary exploration missions. Compared with the myriad of sample preparation techniques available in terrestrial laboratories, the possibilities for sample preparation during in situ missions on other planetary bodies are extremely limited and are generally restricted to abrasion of rock surfaces or crushing of the target samples. Whereas certain techniques need samples to be prepared in powder form, such as X‐ray diffraction, this kind of preparation is not particularly suitable for optical microscopy and/or Raman spectroscopy. In this contribution, we examine the effects of powdering rock and mineral samples on optical observations and Raman analyses. We used a commercial Raman spectrometer, as well as a Raman laser spectrometer that simulates the instrument being developed for the future ExoMars 2018 mission. The commercial Raman spectrometer documents significant modifications to the spectra of the powdered samples, including broadening of the peaks and shifts in their position, as well as the appearance of new peaks. These effects are caused by localised heating of the sample under the laser beam and amplification of nominal surface effects due to the increase in surface area in finer grain sizes. However, most changes observed in the Raman spectra using the Raman laser spectrometer system are negligible because the relatively large (50 µm diameter) laser spot size produces lower irradiance. Furthermore, minor phases were more easily detectable in the powdered samples. Most importantly, however, this sample preparation method results in the loss of the textural features and context, making identification of potential fossilized microbial remains more problematic. Copyright © 2013 John Wiley & Sons, Ltd.

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Structural transformations in laser shock-loaded quartz

Cited by 17 publications

References 25 publications

Influence of quartz anisotropy on shock propagation and spall damage

Influence of quartz anisotropy on shock propagation and spall damage

Laser-induced shock waves in condensed matter: some techniques and applications

Effect of grain size distribution on Raman analyses and the consequences for in situ planetary missions

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