Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Bartosz Pieterek
  • Jakub Ciazela
  • Marine Boulanger
  • Marina Lazarov
  • Anna V. Wegorzewski
  • Magdalena Pańczyk
  • Harald Strauss
  • Henry J.B. Dick
  • Andrzej Muszyński
  • Juergen Koepke
  • Thomas Kuhn
  • Zbigniew Czupyt
  • Lydéric France

Research Organisations

External Research Organisations

  • Adam Mickiewicz University, Poznań
  • Université de Lorraine (UL)
  • Federal Institute for Geosciences and Natural Resources (BGR)
  • Polish Institute of Geology (PIB)
  • University of Münster
  • Woods Hole Oceanographic Institution
  • Polish Academy of Sciences
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Details

Original languageEnglish
Pages (from-to)179-206
Number of pages28
JournalGeochimica et cosmochimica acta
Volume320
Early online date12 Jan 2022
Publication statusPublished - 1 Mar 2022

Abstract

Reactive porous or focused melt flows are common in crystal mushes of mid-ocean ridge magma reservoirs. Although they exert significant control on mid-ocean ridge magmatic differentiation, their role in metal transport between the mantle and the ocean floor remains poorly constrained. Here we aim to improve such knowledge for oceanic crust formed at slow-spreading centers (approximately half of present-day oceanic crust), by focusing on specific igneous features where sulfides are concentrated. International Ocean Discovery Program (IODP) Expedition 360 drilled Hole U1473A 789 m into the lower crust of the Atlantis Bank oceanic core complex, located at the Southwest Indian Ridge. Coarse-grained (5–30 mm) olivine gabbro prevailed throughout the hole, ranging locally from fine- (<1 mm), to very coarse-grained (>30 mm). We studied three distinct intervals of igneous grain size layering at 109.5–110.8, 158.0–158.3, and 593.0–594.4 meters below seafloor to understand the distribution of sulfides. We found that the layer boundaries between the fine- and coarse-grained gabbro were enriched in sulfides and chalcophile elements. On average, sulfide grains throughout the layering were composed of pyrrhotite (81 vol.%; Fe1-xS), chalcopyrite (16 vol.%; CuFeS2), and pentlandite (3 vol.%; [Ni,Fe,Co]9S8), which reflect paragenesis of magmatic origin. The sulfides were most commonly associated with Fe-Ti oxides (titanomagnetites and ilmenites), amphiboles, and apatites located at the interstitial positions between clinopyroxene, plagioclase, and olivine. Pentlandite exsolution textures in pyrrhotite indicate that the sulfides formed from high-temperature sulfide liquid separated from mafic magma that exsolved upon cooling. The relatively homogenous phase proportion within sulfides along with their chemical and isotopic compositions throughout the studied intervals further support the magmatic origin of sulfide enrichment at the layer boundaries. The studied magmatic layers were likely formed as a result of intrusion of more primitive magma (fine-grained gabbro) into the former crystal mush (coarse-grained gabbro). Sulfides from the coarse-grained gabbros are Ir-Platinum Group Element-rich (PGE; i.e., Ir, Os, Ru) but those from the fine-grained gabbros are Pd-PGE-rich (i.e., Pd, Pt, Rh). Notably, the sulfides from the layer boundaries are also enriched in Pd-PGEs, and therefore elevated sulfide contents at the boundaries were likely related to the new intruding melt. Because S concentration at sulfide saturation level is dependent on the Fe content of the melt, sulfide crystallization may have been caused by FeO loss, both via crystallization of late-precipitating oxides at the boundaries, and by exchange of Fe and Mg between melt and Fe-bearing silicates (olivine and clinopyroxene). The increased precipitation of sulfide grains at the layer boundaries might be widespread in the lower oceanic crust, as also observed in the Semail ophiolite and along the Mid-Atlantic Ridge. Therefore, this process might affect the metal budget of the global lower oceanic crust. We estimate that up to ∼20% of the Cu, ∼8% of the S, and ∼84% of the Pb of the oceanic crust inventory is accumulated at the layer boundaries only from the interaction between crystal mush and new magma.

Keywords

    Chalcophile elements, IODP, Lower oceanic crust, Platinum group elements, Sulfides

ASJC Scopus subject areas

Cite this

Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge. / Pieterek, Bartosz; Ciazela, Jakub; Boulanger, Marine et al.
In: Geochimica et cosmochimica acta, Vol. 320, 01.03.2022, p. 179-206.

Research output: Contribution to journalArticleResearchpeer review

Pieterek, B, Ciazela, J, Boulanger, M, Lazarov, M, Wegorzewski, AV, Pańczyk, M, Strauss, H, Dick, HJB, Muszyński, A, Koepke, J, Kuhn, T, Czupyt, Z & France, L 2022, 'Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge', Geochimica et cosmochimica acta, vol. 320, pp. 179-206. https://doi.org/10.1016/j.gca.2022.01.004, https://doi.org/10.15488/13022
Pieterek, B., Ciazela, J., Boulanger, M., Lazarov, M., Wegorzewski, A. V., Pańczyk, M., Strauss, H., Dick, H. J. B., Muszyński, A., Koepke, J., Kuhn, T., Czupyt, Z., & France, L. (2022). Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge. Geochimica et cosmochimica acta, 320, 179-206. https://doi.org/10.1016/j.gca.2022.01.004, https://doi.org/10.15488/13022
Pieterek B, Ciazela J, Boulanger M, Lazarov M, Wegorzewski AV, Pańczyk M et al. Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge. Geochimica et cosmochimica acta. 2022 Mar 1;320:179-206. Epub 2022 Jan 12. doi: 10.1016/j.gca.2022.01.004, 10.15488/13022
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title = "Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge",
abstract = "Reactive porous or focused melt flows are common in crystal mushes of mid-ocean ridge magma reservoirs. Although they exert significant control on mid-ocean ridge magmatic differentiation, their role in metal transport between the mantle and the ocean floor remains poorly constrained. Here we aim to improve such knowledge for oceanic crust formed at slow-spreading centers (approximately half of present-day oceanic crust), by focusing on specific igneous features where sulfides are concentrated. International Ocean Discovery Program (IODP) Expedition 360 drilled Hole U1473A 789 m into the lower crust of the Atlantis Bank oceanic core complex, located at the Southwest Indian Ridge. Coarse-grained (5–30 mm) olivine gabbro prevailed throughout the hole, ranging locally from fine- (<1 mm), to very coarse-grained (>30 mm). We studied three distinct intervals of igneous grain size layering at 109.5–110.8, 158.0–158.3, and 593.0–594.4 meters below seafloor to understand the distribution of sulfides. We found that the layer boundaries between the fine- and coarse-grained gabbro were enriched in sulfides and chalcophile elements. On average, sulfide grains throughout the layering were composed of pyrrhotite (81 vol.%; Fe1-xS), chalcopyrite (16 vol.%; CuFeS2), and pentlandite (3 vol.%; [Ni,Fe,Co]9S8), which reflect paragenesis of magmatic origin. The sulfides were most commonly associated with Fe-Ti oxides (titanomagnetites and ilmenites), amphiboles, and apatites located at the interstitial positions between clinopyroxene, plagioclase, and olivine. Pentlandite exsolution textures in pyrrhotite indicate that the sulfides formed from high-temperature sulfide liquid separated from mafic magma that exsolved upon cooling. The relatively homogenous phase proportion within sulfides along with their chemical and isotopic compositions throughout the studied intervals further support the magmatic origin of sulfide enrichment at the layer boundaries. The studied magmatic layers were likely formed as a result of intrusion of more primitive magma (fine-grained gabbro) into the former crystal mush (coarse-grained gabbro). Sulfides from the coarse-grained gabbros are Ir-Platinum Group Element-rich (PGE; i.e., Ir, Os, Ru) but those from the fine-grained gabbros are Pd-PGE-rich (i.e., Pd, Pt, Rh). Notably, the sulfides from the layer boundaries are also enriched in Pd-PGEs, and therefore elevated sulfide contents at the boundaries were likely related to the new intruding melt. Because S concentration at sulfide saturation level is dependent on the Fe content of the melt, sulfide crystallization may have been caused by FeO loss, both via crystallization of late-precipitating oxides at the boundaries, and by exchange of Fe and Mg between melt and Fe-bearing silicates (olivine and clinopyroxene). The increased precipitation of sulfide grains at the layer boundaries might be widespread in the lower oceanic crust, as also observed in the Semail ophiolite and along the Mid-Atlantic Ridge. Therefore, this process might affect the metal budget of the global lower oceanic crust. We estimate that up to ∼20% of the Cu, ∼8% of the S, and ∼84% of the Pb of the oceanic crust inventory is accumulated at the layer boundaries only from the interaction between crystal mush and new magma.",
keywords = "Chalcophile elements, IODP, Lower oceanic crust, Platinum group elements, Sulfides",
author = "Bartosz Pieterek and Jakub Ciazela and Marine Boulanger and Marina Lazarov and Wegorzewski, {Anna V.} and Magdalena Pa{\'n}czyk and Harald Strauss and Dick, {Henry J.B.} and Andrzej Muszy{\'n}ski and Juergen Koepke and Thomas Kuhn and Zbigniew Czupyt and Lyd{\'e}ric France",
note = "Funding Information: We thank editor D. Teagle, A. Sanfilippo, W. Maier, and an anonymous reviewer for their thorough and insightful comments. This research used samples and data provided by the International Ocean Discovery Program (IODP). IODP is sponsored by the U.S. National Science Foundation (NSF) and participating countries under management of the Consortium for Ocean Leadership (COL). We would like to thank the other Expedition 360 Scientists and the crew of JOIDES Resolution. We thank M. Rechowicz from the Polish Geological Institute – National Research Institute for preparing samples for the SHRIMP measurements, M. Sitnikova from the Bundesanstalt f{\"u}r Geowissenschaften und Rohstoffe for performing SEM MLA analysis, and C. Mandeville, N. Shimizu, A. Fiege from Woods Hole Oceanographic Institution for providing the Sudbury pyrrhotite standard. Further help was provided by A. Duczmal-Czernikiewicz and M. Nowak from the Adam Mickiewicz University, and F. Holtz from the Leibniz University of Hannover, for which we are grateful. This research was funded by National Science Centre Poland (PRELUDIUM 12 no. 2016/23/N/ST10/00288), Graduate Academy of the Leibniz Universit{\"a}t Hannover (60421784), and ECORD Research Grant to J. Ciazela, as well as Deutsche Forschungsgemeinschaft (KO1723/23-1) to J. Koepke and H. Strauss. J. Ciazela is additionally supported within the START program of the Foundation for Polish Science (FNP). This is CRPG contribution No. 2813. ",
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month = mar,
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doi = "10.1016/j.gca.2022.01.004",
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Download

TY - JOUR

T1 - Sulfide enrichment along igneous layer boundaries in the lower oceanic crust

T2 - IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge

AU - Pieterek, Bartosz

AU - Ciazela, Jakub

AU - Boulanger, Marine

AU - Lazarov, Marina

AU - Wegorzewski, Anna V.

AU - Pańczyk, Magdalena

AU - Strauss, Harald

AU - Dick, Henry J.B.

AU - Muszyński, Andrzej

AU - Koepke, Juergen

AU - Kuhn, Thomas

AU - Czupyt, Zbigniew

AU - France, Lydéric

N1 - Funding Information: We thank editor D. Teagle, A. Sanfilippo, W. Maier, and an anonymous reviewer for their thorough and insightful comments. This research used samples and data provided by the International Ocean Discovery Program (IODP). IODP is sponsored by the U.S. National Science Foundation (NSF) and participating countries under management of the Consortium for Ocean Leadership (COL). We would like to thank the other Expedition 360 Scientists and the crew of JOIDES Resolution. We thank M. Rechowicz from the Polish Geological Institute – National Research Institute for preparing samples for the SHRIMP measurements, M. Sitnikova from the Bundesanstalt für Geowissenschaften und Rohstoffe for performing SEM MLA analysis, and C. Mandeville, N. Shimizu, A. Fiege from Woods Hole Oceanographic Institution for providing the Sudbury pyrrhotite standard. Further help was provided by A. Duczmal-Czernikiewicz and M. Nowak from the Adam Mickiewicz University, and F. Holtz from the Leibniz University of Hannover, for which we are grateful. This research was funded by National Science Centre Poland (PRELUDIUM 12 no. 2016/23/N/ST10/00288), Graduate Academy of the Leibniz Universität Hannover (60421784), and ECORD Research Grant to J. Ciazela, as well as Deutsche Forschungsgemeinschaft (KO1723/23-1) to J. Koepke and H. Strauss. J. Ciazela is additionally supported within the START program of the Foundation for Polish Science (FNP). This is CRPG contribution No. 2813.

PY - 2022/3/1

Y1 - 2022/3/1

N2 - Reactive porous or focused melt flows are common in crystal mushes of mid-ocean ridge magma reservoirs. Although they exert significant control on mid-ocean ridge magmatic differentiation, their role in metal transport between the mantle and the ocean floor remains poorly constrained. Here we aim to improve such knowledge for oceanic crust formed at slow-spreading centers (approximately half of present-day oceanic crust), by focusing on specific igneous features where sulfides are concentrated. International Ocean Discovery Program (IODP) Expedition 360 drilled Hole U1473A 789 m into the lower crust of the Atlantis Bank oceanic core complex, located at the Southwest Indian Ridge. Coarse-grained (5–30 mm) olivine gabbro prevailed throughout the hole, ranging locally from fine- (<1 mm), to very coarse-grained (>30 mm). We studied three distinct intervals of igneous grain size layering at 109.5–110.8, 158.0–158.3, and 593.0–594.4 meters below seafloor to understand the distribution of sulfides. We found that the layer boundaries between the fine- and coarse-grained gabbro were enriched in sulfides and chalcophile elements. On average, sulfide grains throughout the layering were composed of pyrrhotite (81 vol.%; Fe1-xS), chalcopyrite (16 vol.%; CuFeS2), and pentlandite (3 vol.%; [Ni,Fe,Co]9S8), which reflect paragenesis of magmatic origin. The sulfides were most commonly associated with Fe-Ti oxides (titanomagnetites and ilmenites), amphiboles, and apatites located at the interstitial positions between clinopyroxene, plagioclase, and olivine. Pentlandite exsolution textures in pyrrhotite indicate that the sulfides formed from high-temperature sulfide liquid separated from mafic magma that exsolved upon cooling. The relatively homogenous phase proportion within sulfides along with their chemical and isotopic compositions throughout the studied intervals further support the magmatic origin of sulfide enrichment at the layer boundaries. The studied magmatic layers were likely formed as a result of intrusion of more primitive magma (fine-grained gabbro) into the former crystal mush (coarse-grained gabbro). Sulfides from the coarse-grained gabbros are Ir-Platinum Group Element-rich (PGE; i.e., Ir, Os, Ru) but those from the fine-grained gabbros are Pd-PGE-rich (i.e., Pd, Pt, Rh). Notably, the sulfides from the layer boundaries are also enriched in Pd-PGEs, and therefore elevated sulfide contents at the boundaries were likely related to the new intruding melt. Because S concentration at sulfide saturation level is dependent on the Fe content of the melt, sulfide crystallization may have been caused by FeO loss, both via crystallization of late-precipitating oxides at the boundaries, and by exchange of Fe and Mg between melt and Fe-bearing silicates (olivine and clinopyroxene). The increased precipitation of sulfide grains at the layer boundaries might be widespread in the lower oceanic crust, as also observed in the Semail ophiolite and along the Mid-Atlantic Ridge. Therefore, this process might affect the metal budget of the global lower oceanic crust. We estimate that up to ∼20% of the Cu, ∼8% of the S, and ∼84% of the Pb of the oceanic crust inventory is accumulated at the layer boundaries only from the interaction between crystal mush and new magma.

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