Cathodoluminescence and Raman Spectroscopic Characterization of Experimentally Shocked Plagioclase

Kayama, Masahiro; Nishido, Hirotsugu; Ninagawa, K.; Tsuchiyama, A.; Gucsik, A.

doi:10.1063/1.3222897

Cited by 20 publications

(38 citation statements)

References 7 publications

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“…3b) [4]. Similar Raman spectra have been reported in previous Raman study on maskelynite in shergottites [5].…”

Section: Discussionsupporting

confidence: 74%

“…CL intensities at 380 nm decrease with an increase in electron irradiation time. Such behavior is similar to short-lived luminescence reported in CL spectra of silica minerals [7]. The luminescence center related to emission at 380 nm might be eliminated by electron irradiation.…”

Section: Discussionsupporting

confidence: 66%

“…3a). Similar UV-blue has been also observed in plagioclase experimentally shocked at 30 and 40 GPa [4]. Maskelynite indicates a rapid decay of its emission during electron irradiation, where CL intensity at 380 nm decreases with an increase in irradiation time at 15 kV accelerating voltage and 2.0 nA beam current.…”

Section: Resultssupporting

confidence: 57%

“…Plagioclase in terrestrial rocks often have emission bands at around 420, 560 and 750 nm in blue, yellow and red regions which are assigned to Al-O --Al, Mn 2+ and Fe 3+ center, respectively [6]. Furthermore, an emission band at around 380 nm has not been found in CL spectra of natural and synthetic plagioclase except for experimentally shocked ones at 30 and 40 GPa [4]. According to Kayama et al [4], plagioclase experimentally shocked at 30 GPa represents a dull emission in UV-blue and yellow spectral regions, and that at 40 GPa shows only an emission band with high intensity at around 380 nm [4].…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, an emission band at around 380 nm has not been found in CL spectra of natural and synthetic plagioclase except for experimentally shocked ones at 30 and 40 GPa [4]. According to Kayama et al [4], plagioclase experimentally shocked at 30 GPa represents a dull emission in UV-blue and yellow spectral regions, and that at 40 GPa shows only an emission band with high intensity at around 380 nm [4]. This emission band at around 380 nm might be assigned to a shock-induced luminescence center, suggesting a CL signal characteristic of maskelynite.…”

Section: Discussionmentioning

confidence: 99%

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Cathodoluminescence Characterization of Maskelynite and Alkali Feldspar in Shergottite (Dhofar 019)

Kayama¹,

Nakazato²,

Nishido³

et al. 2009

AIP Conference Proceedings

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Dhofar 019 is classified as an olivine-bearing basaltic shergottite and consists of subhedral grains of pyroxene, olivine, feldspar mostly converted to maskelynite and minor alkali feldspar. The CL spectrum of its maskelynite exhibits an emission band at around 380 nm Similar UV-blue emission has been observed in the plagioclase experimentally shocked at 30 and 40 GPa, but not in terrestrial plagioclase. This UV-blue emission is a notable characteristic of maskelynite. CL spectrum of alkali feldspar in Dhofar 019 has an emission bands at around 420 nm with no red emission. Terrestrial alkali feldspar actually consists of blue and red emission at 420 and 710 nm assigned to Al-O --Al and Fe 3+ centers, respectively. Maskelynite shows weak and broad Raman spectral peaks at around 500 and 580 cm -1 . The Raman spectrum of alkali feldspar has a weak peak at 520 cm -1 , whereas terrestrial counterpart shows the emission bands at 280, 400, 470, 520 and 1120 cm -1 . Shock pressure on this meteorite transformed plagioclase and alkali feldspar into maskelynite and almost glass phase, respectively. It eliminates their luminescence centers, responsible for disappearance of yellow and/or red emission in CL of maskelynite and alkali feldspar. The absence of the red emission band in alkali feldspar can also be due to the lack of Fe3+ in the feldspar as it was reported for some lunar feldspars.

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“…3b) [4]. Similar Raman spectra have been reported in previous Raman study on maskelynite in shergottites [5].…”

Section: Discussionsupporting

confidence: 74%

Section: Discussionsupporting

confidence: 66%

Section: Resultssupporting

confidence: 57%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 3 more Smart Citations

Cathodoluminescence Characterization of Maskelynite and Alkali Feldspar in Shergottite (Dhofar 019)

Kayama¹,

Nakazato²,

Nishido³

et al. 2009

AIP Conference Proceedings

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Calibration of Raman bandwidth in large Raman images using a mercury–argon lamp

Jakubek

Fries

2020

J Raman Spectroscopy

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Raman imaging has proven to be an important tool in the analysis of astromaterials. Raman imaging can describe the composition and mineralogy of astromaterials in a nondestructive manner preserving precious samples for additional study. Raman bandwidth is a common spectroscopic marker used to elucidate information such as composition, latent strain, and thermal processing history. The observed Raman bandwidth of a sample is a result of a convolution of the true Raman lineshape and the spectrometer's slit function. Thus, to compare Raman bandwidths across spectra and instruments, one needs to calibrate the Raman spectrum to account for effects of the slit function. Astromaterials are heterogeneous requiring the collection of large Raman images for adequate sampling. It is well known that the wavenumber calibration of an instrument drifts with time throughout Raman image collection. Here, we find that the spectrometer slit function also varies with time and laboratory temperature throughout Raman image collection. We utilize a mercury–argon (Hg–Ar) lamp integrated into our Raman microscope in a novel manner to calibrate the bandwidth in each Raman spectrum within our Raman image. We can do this because the narrow Hg–Ar lamp emission lines approximate the spectrometer slit function for each Raman spectrum allowing for the calculation of the true Raman bandwidth from each Raman spectrum within the Raman image. Our technique allows for the comparison of Raman bandwidth throughout a Raman image and between Raman images/spectra collected using different instruments, facilitating scientific analyses that are reproducible across multiple laboratories.

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Shock-induced deformation of Shergottites: Shock-pressures and perturbations of magmatic ages on Mars

Goresy

Gillet

Miyahara

et al. 2013

Geochimica et Cosmochimica Acta

111

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Cathodoluminescence and Raman Spectroscopic Characterization of Experimentally Shocked Plagioclase

Cited by 20 publications

References 7 publications

Cathodoluminescence Characterization of Maskelynite and Alkali Feldspar in Shergottite (Dhofar 019)

Cathodoluminescence Characterization of Maskelynite and Alkali Feldspar in Shergottite (Dhofar 019)

Calibration of Raman bandwidth in large Raman images using a mercury–argon lamp

Shock-induced deformation of Shergottites: Shock-pressures and perturbations of magmatic ages on Mars

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