Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates: II. Tourmalines

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Anke Watenphul
  • Martina Burgdorf
  • Jochen Schlüter
  • Ingo Horn
  • Thomas Malcherek
  • Boriana Mihailova

Research Organisations

External Research Organisations

  • Universität Hamburg
View graph of relations

Details

Original languageEnglish
Pages (from-to)970-985
Number of pages16
JournalAmerican mineralogist
Volume101
Issue number4
Publication statusPublished - 1 Apr 2016

Abstract

A detailed Raman spectroscopic, electron microprobe, and laser ablation-induced coupled plasma-mass spectrometric study of 46 natural tourmalines [XY3Z6(T6O18)(BO3)3V3W] from 10 subgroups was performed to evaluate the potential of the Raman scattering, in particular of the OH bond stretching vibrations, for the identification of tourmaline species and site-occupancy analysis. The widespread chemical variety of the studied samples is reflected in the different spectral shapes. The positions and intensities of the observed vibrational modes can be used for tourmaline species identification. Taking into account the charge of the Y- and Z-site cations as well as the X-site occupancy, the Raman peaks generated by the bond stretching mode of the VOH groups were attributed to different YZZ-YZZ-YZZ cationic configurations, while the peaks originating from WOH stretching is due to chemically different YYY triplets next to an X-site vacancy, X Na, or X Ca. It is shown that the integrated intensities of the VOH-stretching peaks can be used to calculate the contents of the major Y-site elements Mg, (Fe2++Mn2+), Li, and Al. The analysis of the VOH-peak positions yields information on the X-site occupancy. The fitted linear equations can be used to determine the content of X (Na+Ca) and X-site vacancy per formula unit. Guidelines for how to gain crystallochemical information from the Raman spectra of tourmaline are suggested. This study, along with Part 1 dedicated to amphiboles (Leissner et al. 2015), reveals that Raman spectroscopy is well suited as a non-destructive, preparation-free, and easy-to-handle method for species identification and site-occupancy analysis in complex hydrous silicate. Our results demonstrate that the chemistry on the non-tetrahedral positions substantially influences the Raman-active H-O bond stretching phonon modes, which allows for quantitative compositional analysis, including the content of lithium.

Keywords

    electron microprobe analysis, LA ICP-MS, Raman spectroscopy, Tourmaline

ASJC Scopus subject areas

Cite this

Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates: II. Tourmalines. / Watenphul, Anke; Burgdorf, Martina; Schlüter, Jochen et al.
In: American mineralogist, Vol. 101, No. 4, 01.04.2016, p. 970-985.

Research output: Contribution to journalArticleResearchpeer review

Watenphul, A, Burgdorf, M, Schlüter, J, Horn, I, Malcherek, T & Mihailova, B 2016, 'Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates: II. Tourmalines', American mineralogist, vol. 101, no. 4, pp. 970-985. https://doi.org/10.2138/am-2016-5530
Watenphul A, Burgdorf M, Schlüter J, Horn I, Malcherek T, Mihailova B. Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates: II. Tourmalines. American mineralogist. 2016 Apr 1;101(4):970-985. doi: 10.2138/am-2016-5530
Watenphul, Anke ; Burgdorf, Martina ; Schlüter, Jochen et al. / Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates : II. Tourmalines. In: American mineralogist. 2016 ; Vol. 101, No. 4. pp. 970-985.
Download
@article{a5b8918c9bdb4ce7af43df230f49ba56,
title = "Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates: II. Tourmalines",
abstract = "A detailed Raman spectroscopic, electron microprobe, and laser ablation-induced coupled plasma-mass spectrometric study of 46 natural tourmalines [XY3Z6(T6O18)(BO3)3V3W] from 10 subgroups was performed to evaluate the potential of the Raman scattering, in particular of the OH bond stretching vibrations, for the identification of tourmaline species and site-occupancy analysis. The widespread chemical variety of the studied samples is reflected in the different spectral shapes. The positions and intensities of the observed vibrational modes can be used for tourmaline species identification. Taking into account the charge of the Y- and Z-site cations as well as the X-site occupancy, the Raman peaks generated by the bond stretching mode of the VOH groups were attributed to different YZZ-YZZ-YZZ cationic configurations, while the peaks originating from WOH stretching is due to chemically different YYY triplets next to an X-site vacancy, X Na, or X Ca. It is shown that the integrated intensities of the VOH-stretching peaks can be used to calculate the contents of the major Y-site elements Mg, (Fe2++Mn2+), Li, and Al. The analysis of the VOH-peak positions yields information on the X-site occupancy. The fitted linear equations can be used to determine the content of X (Na+Ca) and X-site vacancy per formula unit. Guidelines for how to gain crystallochemical information from the Raman spectra of tourmaline are suggested. This study, along with Part 1 dedicated to amphiboles (Leissner et al. 2015), reveals that Raman spectroscopy is well suited as a non-destructive, preparation-free, and easy-to-handle method for species identification and site-occupancy analysis in complex hydrous silicate. Our results demonstrate that the chemistry on the non-tetrahedral positions substantially influences the Raman-active H-O bond stretching phonon modes, which allows for quantitative compositional analysis, including the content of lithium.",
keywords = "electron microprobe analysis, LA ICP-MS, Raman spectroscopy, Tourmaline",
author = "Anke Watenphul and Martina Burgdorf and Jochen Schl{\"u}ter and Ingo Horn and Thomas Malcherek and Boriana Mihailova",
year = "2016",
month = apr,
day = "1",
doi = "10.2138/am-2016-5530",
language = "English",
volume = "101",
pages = "970--985",
journal = "American mineralogist",
issn = "0003-004X",
publisher = "Walter de Gruyter GmbH",
number = "4",

}

Download

TY - JOUR

T1 - Exploring the potential of Raman spectroscopy for crystallochemical analyses of complex hydrous silicates

T2 - II. Tourmalines

AU - Watenphul, Anke

AU - Burgdorf, Martina

AU - Schlüter, Jochen

AU - Horn, Ingo

AU - Malcherek, Thomas

AU - Mihailova, Boriana

PY - 2016/4/1

Y1 - 2016/4/1

N2 - A detailed Raman spectroscopic, electron microprobe, and laser ablation-induced coupled plasma-mass spectrometric study of 46 natural tourmalines [XY3Z6(T6O18)(BO3)3V3W] from 10 subgroups was performed to evaluate the potential of the Raman scattering, in particular of the OH bond stretching vibrations, for the identification of tourmaline species and site-occupancy analysis. The widespread chemical variety of the studied samples is reflected in the different spectral shapes. The positions and intensities of the observed vibrational modes can be used for tourmaline species identification. Taking into account the charge of the Y- and Z-site cations as well as the X-site occupancy, the Raman peaks generated by the bond stretching mode of the VOH groups were attributed to different YZZ-YZZ-YZZ cationic configurations, while the peaks originating from WOH stretching is due to chemically different YYY triplets next to an X-site vacancy, X Na, or X Ca. It is shown that the integrated intensities of the VOH-stretching peaks can be used to calculate the contents of the major Y-site elements Mg, (Fe2++Mn2+), Li, and Al. The analysis of the VOH-peak positions yields information on the X-site occupancy. The fitted linear equations can be used to determine the content of X (Na+Ca) and X-site vacancy per formula unit. Guidelines for how to gain crystallochemical information from the Raman spectra of tourmaline are suggested. This study, along with Part 1 dedicated to amphiboles (Leissner et al. 2015), reveals that Raman spectroscopy is well suited as a non-destructive, preparation-free, and easy-to-handle method for species identification and site-occupancy analysis in complex hydrous silicate. Our results demonstrate that the chemistry on the non-tetrahedral positions substantially influences the Raman-active H-O bond stretching phonon modes, which allows for quantitative compositional analysis, including the content of lithium.

AB - A detailed Raman spectroscopic, electron microprobe, and laser ablation-induced coupled plasma-mass spectrometric study of 46 natural tourmalines [XY3Z6(T6O18)(BO3)3V3W] from 10 subgroups was performed to evaluate the potential of the Raman scattering, in particular of the OH bond stretching vibrations, for the identification of tourmaline species and site-occupancy analysis. The widespread chemical variety of the studied samples is reflected in the different spectral shapes. The positions and intensities of the observed vibrational modes can be used for tourmaline species identification. Taking into account the charge of the Y- and Z-site cations as well as the X-site occupancy, the Raman peaks generated by the bond stretching mode of the VOH groups were attributed to different YZZ-YZZ-YZZ cationic configurations, while the peaks originating from WOH stretching is due to chemically different YYY triplets next to an X-site vacancy, X Na, or X Ca. It is shown that the integrated intensities of the VOH-stretching peaks can be used to calculate the contents of the major Y-site elements Mg, (Fe2++Mn2+), Li, and Al. The analysis of the VOH-peak positions yields information on the X-site occupancy. The fitted linear equations can be used to determine the content of X (Na+Ca) and X-site vacancy per formula unit. Guidelines for how to gain crystallochemical information from the Raman spectra of tourmaline are suggested. This study, along with Part 1 dedicated to amphiboles (Leissner et al. 2015), reveals that Raman spectroscopy is well suited as a non-destructive, preparation-free, and easy-to-handle method for species identification and site-occupancy analysis in complex hydrous silicate. Our results demonstrate that the chemistry on the non-tetrahedral positions substantially influences the Raman-active H-O bond stretching phonon modes, which allows for quantitative compositional analysis, including the content of lithium.

KW - electron microprobe analysis

KW - LA ICP-MS

KW - Raman spectroscopy

KW - Tourmaline

UR - http://www.scopus.com/inward/record.url?scp=84964829429&partnerID=8YFLogxK

U2 - 10.2138/am-2016-5530

DO - 10.2138/am-2016-5530

M3 - Article

AN - SCOPUS:84964829429

VL - 101

SP - 970

EP - 985

JO - American mineralogist

JF - American mineralogist

SN - 0003-004X

IS - 4

ER -