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Crystallographic and fluid compositional effects on the halogen (Cl, F, Br, I) incorporation in pyromorphite-group minerals

  • Tatjana Epp EMAIL logo , Michael A.W. Marks , Thomas Ludwig , Mark A. Kendrick , Nelson Eby , Harald Neidhardt , Yvonne Oelmann and Gregor Markl
Published/Copyright: November 2, 2019
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American Mineralogist
From the journal American Mineralogist Volume 104 Issue 11

Abstract

Pyromorphite-group minerals (PyGM), mainly pyromorphite [Pb5(PO4)3Cl], mimetite [Pb5(AsO4)3Cl], and vanadinite [Pb5(VO4)3Cl], are common phases that form by supergene weathering of galena. Their formation is strongly influenced by processes at the Earth’s surface and in the soil overlying a lead deposit, and they incorporate high amounts of halogens, mostly Cl and, in some cases, F. The abundance of Br and I in natural PyGM and their potential as process tracers during surface and sub-surface fluid-rock interaction processes has not been investigated in detail due to analytical difficulties. We, therefore, developed methods for the simultaneous determination of Cl, F, Br, and I in PyGM for (1) powdered bulk samples via combustion ion chromatography (CIC) and (2) compositionally zoned crystals by means of secondary ion mass spectrometry (SIMS).

Our study is based on well-characterized samples of pyromorphite (N = 38), mimetite (N = 16), and vanadinite (N = 2) from Schwarzwald (Germany). Natural pyromorphite incorporates more I (up to 26 μg/g) than mimetite (up to 2 μg/g) and vanadinite (up to 1 μg/g), while Br contents are higher in mimetite (up to 20 μg/g) and vanadinite (up to 13 μg/g) compared to pyromorphite (less than 4 μg/g). These results are unexpected, as mimetite and vanadinite have longer As/V-O bonds giving them larger unit cells and larger polyhedral volumes for the Cl site in the Pb26 octahedron than pyromorphite. Accordingly, pyromorphite was expected to preferentially incorporate Br rather than I, but the opposite is observed. Hence, halogen chemistry of PyGM is probably not governed by a crystal-chemical control (alone) but by fluid composition. However, the exact reasons remain enigmatic. This idea is corroborated by spatially resolved SIMS analyses that show that many pyromorphite-group minerals are strongly zoned with respect to their halogen mass ratios (e.g., Br/Cl, Br/I mass ratios). Furthermore, variations in halogen abundance ratios do not correlate with Ca/Pb, P/As, or P/V ratios and therefore may record alternating and season-dependent environmental parameters including biological activity, vegetation density, physico-chemical soil properties, and rainfall rate. We suggest that the zonation reflects multiple single fluid flow episodes and, hence, records surface processes. However, further experiments concerning the fractionation of halogens between fluid and PyGM are needed before halogen ratios in pyromorphite-group minerals can be used as reliable monitors of fluid-driven processes.

Keywords: Bromine; iodine; combustion ion chromatography; pyromorphite; mimetite; vanadinite

Acknowledgments

We are grateful to Thomas Wenzel for his invaluable help with the electron microprobe. Simone Schafflick is thanked for the sample preparation. Further thanks go to Bernd Steinhilber, who helped to develop the ideal method for the analyses. Axel Schmitt is thanked for providing the Macusani glass sample. Furthermore, we thank the Editor Don Baker, the Associate Editor Andrew Madden, and two anonymous reviewers for their constructive feedback that improved this manuscript significantly.

  1. Funding

    This research was funded by the German Research Foundation (DFG) Grant No. MA 2135/23-1 and OE 516/8-1. M.A. Kendrick was supported by an Australian Research Council Future Fellowship (FT13 0100141).

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Received: 2019-03-28
Accepted: 2019-07-26
Published Online: 2019-11-02
Published in Print: 2019-11-26

© 2019 Walter de Gruyter GmbH, Berlin/Boston

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  8. Controls on tetrahedral Fe(III) abundance in 2:1 phyllosilicates
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https://doi.org/10.2138/am-2019-7068
Keywords for this article
Bromine; iodine; combustion ion chromatography; pyromorphite; mimetite; vanadinite

Articles in the same Issue

  1. Crossroads in Earth and Planetary Materials
  2. Computer modeling of apparently straight bond angles: The intriguing case of all-silica ferrierite
  3. Composite materials based on zeolite stilbite from Faroe Islands for the removal of fluoride from drinking water
  4. The Italian Solfatara as an analog for Mars fumarolic alteration
  5. Change of crackling noise in granite by thermal damage: Monitoring nuclear waste deposits
  6. Constraining the timing and character of crustal melting in the Adirondack Mountains using multi-scale compositional mapping and in-situ monazite geochronology
  7. Melting in the Fe-FeO system to 204 GPa: Implications for oxygen in Earth’s core
  8. Controls on tetrahedral Fe(III) abundance in 2:1 phyllosilicates
  9. Stability, composition, and crystal structure of Fe-bearing Phase E in the transition zone
  10. Enrichment of manganese to spessartine saturation in granite-pegmatite systems
  11. Al and Si diffusion in rutile
  12. Sound velocity of neon at high pressures and temperatures by Brillouin scattering
  13. A Cr3+ luminescence study of natural topaz Al2SiO4(F,OH)2 up to 60 GPa
  14. Two generations of exsolution lamellae in pyroxene from Asuka 09545: Clues to the thermal evolution of silicates in mesosiderite
  15. Crystallographic and fluid compositional effects on the halogen (Cl, F, Br, I) incorporation in pyromorphite-group minerals
  16. Diffusion of F and Cl in dry rhyodacitic melt
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