Abstract

We determined the halogen (F, Cl, Br, and I) and sulfur (S) concentrations in Cl-rich rock-forming minerals from five peralkaline complexes. We investigated sodalite (N = 42), eudialyte-group minerals (N = 84), and tugtupite (N = 8) from representative rock samples derived from Ilímaussaq (South Greenland), Norra Kärr (Sweden), Tamazeght (Morocco), Lovozero, and Khibina (Russian Federation). Taken together, sodalite and eudialyte-group minerals dominate the Cl and Br budget of the investigated rocks. For F, however, several other phases (e.g., amphibole, fluorite, villiaumite, and minerals of the rinkite group and the apatite supergroup) are additional sinks, and parts of the S may be scavenged in generally rare sulfides. The investigated minerals contain Cl at the wt.% level, F and S concentrations are in the hundreds to thousands of µg/g-range, Br is less common (0.2–200 µg/g) and I is rare (mostly well below 1 µg/g). Normalized to Cl, sodalite prefers Br relative to eudialyte-group minerals, while F is always enriched in the latter. Our data show that both F and S may represent important components in eudialyte-group minerals, sometimes at similar levels as Cl, which normally dominates. Sulfur reveals redox-dependent behavior: Under reduced crystallization conditions, S is more compatible in eudialyte-group minerals (EGM) than in sodalite, which flips to the opposite under water-rich and presumably more oxidized conditions. We investigate the applicability of F/Cl, Br/Cl, and S/Cl ratios in these minerals in peralkaline systems to better understand the interplay of magmatic differentiation, fluid loss and hydrothermal overprint. Similar to apatite in metaluminous systems, fractionation of sodalite, and eudialyte-group minerals in peralkaline magmas leads to decreasing Br/Cl ratios. The data presented in this study bear implications for the mineral chemistry and compositional variation of sodalite and especially EGM in general. Volatile components in EGM that are not normally considered, such as F and S, can reach concentrations of thousands of µg/g. Especially in the case of F, with its low atomic weight, the results obtained in this study indicate that it is very significant for formulae calculations, neutral charge-balance, and similar aspects at such concentration levels. This study demonstrates that halogen contents and ratios are sensitive monitors for a variety of processes in magmatic-hydrothermal systems, including magmatic fractionation, volatile loss, and fluid–rock interaction.

Highlights

  • Understanding the behavior of halogens in magmatic processes is essential for estimating global halogen budgets and exchanges between the different Earth system reservoirs

  • Tugtupite and eudialyte-group minerals (EGM) were produced by crushing and sieving rock samples and subsequent standard magnetic and heavy liquid separation techniques

  • Bulk halogen (F, Cl, Br, and I) and S analyses were done by Combustion Ion Chromatography (CIC) using a 930 Metrohm Combustion IC PP

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Summary

Introduction

Understanding the behavior of halogens in magmatic processes is essential for estimating global halogen budgets and exchanges between the different Earth system reservoirs. The role of magmatism in mediating halogen fluxes between these reservoirs is important for several reasons, including their capacity for transporting metals in fluids (e.g., in ore-forming processes) and their environmental impact on the atmosphere during magmatic degassing and fluid exsolution [1,2]. Besides H2 O, CO2 , and S, halogens are important components of magmatic fluids and volcanic gases. Br and I are significant components in volcanic gases [3,4,5], and it was demonstrated that Br species in the stratosphere are notably involved in the destruction of ozone, being much more efficient than Cl in this respect [6]. As recently pointed out [2], the understanding of the geochemical cycle of the less abundant halogens Br and I [7] and establishing reliable analytical methods for their determination in geological materials [8,9,10,11,12] are important challenges

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