Compressional pathways of α-cristobalite, structure of cristobalite X-I, and towards the understanding of seifertite formation

Černok, Ana; Marquardt, Katharina; Caracas, Razvan; Bykova, Elena; Habler, Gerlinde; Liermann, Hanns‐Peter; Hanfland, Michael; Mézouar, M.; Bobocioiu, Ema; Dubrovinsky, Leonid

doi:10.1038/ncomms15647

Cited by 42 publications

(55 citation statements)

References 58 publications

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“…For example in Martian meteorites, the shock pressure and temperature conditions (Fritz et al 2005a, 2005b) were found to be highly consistent with a thermal history inferred from a variety of independent properties, including (1) the radiogenic 4 He inventory (Schwenzer et al 2008), (2) the magnetic properties of ALH84001 (Weiss et al 2000); (3) the recrystallization of plagioclase in a decimeter-sized rock that cooled in space (Fritz et al 2005a), (4) the formation of seifertite enclosed in maskelynite in the Shergotty meteorite (Sharp et al 1999;Bl€ aß 2013;Kubo et al 2015;Cernok et al 2017; this work), and (5) the formation and preservation of thermally unstable high pressure phases associated with shock-produced melt veins and pockets in some meteorites (Fritz et al 2017;Tomioka and Miyahara 2017;Bischoff et al 2019). The low temperature solid state formation of maskelynite does not reset the 40 Ar-39 Ar chronometer of rocks, as Ar diffusion requires a prolonged heating regime (Jessberger and Ostertag 1982;Fernandes et al 2009;Shuster et al 2010).…”

Section: Discussionsupporting

confidence: 54%

“…; Cernok et al. ; this work), and (5) the formation and preservation of thermally unstable high pressure phases associated with shock‐produced melt veins and pockets in some meteorites (Fritz et al. ; Tomioka and Miyahara ; Bischoff et al.…”

Section: Discussionmentioning

confidence: 77%

“…; Cernok et al. ). Thus, the presence of seifertite in maskelynite of the Shergotty meteorite is consistent with a low temperature formation at shock pressures of 30 GPa as deduced from the shock effects in the rock‐forming minerals, including maskelynite with a high RI (Stöffler et al.…”

Section: Discussionmentioning

confidence: 97%

“…In a high temperature environment (>1000 K), seifertite is stable at pressures higher than the stability field of stishovite; i.e., depending on the temperature, it requires pressures in excess of 60-80 GPa (Sharp et al 1999;Dubrovinsky et al 2001;El Goresy et al 2004). Lower temperatures inhibit the formation of stishovite, and seifertite can form from cristobalite at low temperatures (~480 K) and hydrostatic pressure of 25 GPa (Bl€ aß 2013;Kubo et al 2015;Cernok et al 2017). Thus, the presence of seifertite in maskelynite of the Shergotty meteorite is consistent with a low temperature formation at shock pressures of 30 GPa as deduced from the shock effects in the rock-forming minerals, including maskelynite with a high RI (St€ offler et al 1986;Fritz et al 2005a).…”

Section: Solid State Formation Of Diaplectic Glasses and Seifertite Imentioning

confidence: 99%

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On the formation of diaplectic glass: Shock and thermal experiments with plagioclase of different chemical compositions

Fritz¹,

Fernandes

Greshake

et al. 2019

Meteorit & Planetary Scien

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This contribution addresses the role of chemical composition, pressure, temperature, and time during the shock transformation of plagioclase into diaplectic glass—i.e., maskelynite. Plagioclase of An50‐57 and An94 was recovered as almost fully isotropic maskelynite from room temperature shock experiments at 28 and 24 GPa. The refractive index (RI) decreased to values of a quenched mineral glass for An50‐57 plagioclase shocked to 45 GPa and shows a maximum in An94 plagioclase shocked to 41.5 GPa. The An94 plagioclase experiments can serve as shock thermobarometer for lunar highland rocks and howardite, eucrite, and diogenite meteorites. Shock experiments at 28, 32, 36, and 45 GPa and initial temperatures of 77 and 293 K on plagioclase (An50‐57) produced materials with identical optical and Raman spectroscopic properties. In the low temperature (<540 K) region, the formation of maskelynite is entirely controlled by shock pressure. The RI of maskelynite decreased in heating experiments of 5 min at temperatures of >770 K, thus, providing a conservative upper limit for the postshock temperature history of the rock. Although shock recovery experiments and static pressure experiments differ by nine orders of magnitude in typical time scale (microseconds versus hours), the amorphization of plagioclase occurs at similar pressure and temperature conditions with both methods. The experimental shock calibration of plagioclase can, together with other minerals, be used as shock thermobarometer for naturally shocked rocks.

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Section: Discussionsupporting

confidence: 54%

Section: Discussionmentioning

confidence: 77%

Section: Discussionmentioning

confidence: 97%

Section: Solid State Formation Of Diaplectic Glasses and Seifertite Imentioning

confidence: 99%

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On the formation of diaplectic glass: Shock and thermal experiments with plagioclase of different chemical compositions

Fritz¹,

Fernandes

Greshake

et al. 2019

Meteorit & Planetary Scien

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“…2c), a few pronounced peaks become apparent. They coincide with vibrational signatures of the cristobalite 18 and tetragonal zirconia 19 phases, which are formed at high temperatures 20,21 . Figure 3 shows X-ray diffraction (XRD) data of annealed powder samples.…”

Section: Resultssupporting

confidence: 69%

Additive-Manufacturing of 3D Glass-Ceramics down to Nanoscale Resolution

Gailevičius¹,

Padolskytė²,

Mikoliūnaitė³

et al. 2018

Preprint

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Fabrication of a true-3D inorganic ceramic with resolution down to nanoscale using sol-gel resist precursor is demonstrated. The method has an unrestricted free-form capability, control of the fill-factor, and high fabrication throughput. A systematic study of the proposed approach based on ultrafast laser 3D lithography of organic-inorganic hybrid sol-gel resin followed by a heat treatment enabled formation of inorganic amorphous and crystalline composites guided by the composition of the initial resin. The achieved resolution of 100 nm was obtained for 3D patterns of complex free-form architectures. Fabrication throughput of 50×103 voxels/s is achieved; voxel - a single volume element was recorded by a single pulse exposure. After a subsequent thermal treatment, ceramic phase was formed depending on the temperature and duration of the heat treatment as validated by Raman micro-spectroscopy. The X-ray diffraction (XRD) revealed a gradual emergence of the crystalline phases at higher temperatures with a signature of cristobalite SiO2, a high-temperature polymorph. Also, the tetragonal ZrO2 phase known for its high fracture strength was observed. This 3D nano-sintering technique is scalable from nano- to millimeter dimensions and opens a conceptually novel route for optical 3D nano-printing of various crystalline inorganic materials defined by an initial composition for diverse applications for microdevices in harsh physical and chemical environments and high temperatures.

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Occurrence and origin of opaline silica in the Mesoarchean Bangur chromite deposit, Singhbhum Craton, India

Debata

Nayak

2021

J Earth Syst Sci

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Compressional pathways of α-cristobalite, structure of cristobalite X-I, and towards the understanding of seifertite formation

Cited by 42 publications

References 58 publications

On the formation of diaplectic glass: Shock and thermal experiments with plagioclase of different chemical compositions

On the formation of diaplectic glass: Shock and thermal experiments with plagioclase of different chemical compositions

Additive-Manufacturing of 3D Glass-Ceramics down to Nanoscale Resolution

Occurrence and origin of opaline silica in the Mesoarchean Bangur chromite deposit, Singhbhum Craton, India

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