Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Barbara Zihlmann
  • Samuel Müller
  • Rosalind M. Coggon
  • Jürgen Koepke
  • Dieter Garbe-Schönberg
  • Damon A.H. Teagle

Organisationseinheiten

Externe Organisationen

  • University of Southampton
  • Christian-Albrechts-Universität zu Kiel (CAU)
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Details

OriginalspracheEnglisch
Seiten (von - bis)103-124
Seitenumfang22
FachzeitschriftLithos
Jahrgang323
Frühes Online-Datum13 Sept. 2018
PublikationsstatusVeröffentlicht - 15 Dez. 2018

Abstract

Hydrothermal circulation is a key process for chemical and isotopic exchange between the solid Earth and oceans, and for the extraction of heat from newly accreted crust at mid-ocean ridges. However, due to a dearth of samples from intact oceanic crust, or continuous sample suites from ophiolites, there remain major shortcomings in our understanding of hydrothermal circulation in the oceanic crust, especially in the lower plutonic crust. In particular, it remains unknown whether fluid recharge and discharge occurs pervasively or if it is mainly channelled within discrete zones such as faults. Here, we describe a hydrothermally-altered fault zone that crops out in the Wadi Gideah in the layered gabbro section of the Samail ophiolite of Oman. A one metre thick normal fault comprising deformed chlorite ± epidote fault rock with disseminated chalcopyrite and pyrite, offsets gently dipping layered olivine gabbros. The chlorite-rich fault rocks surround strongly altered clasts of layered gabbro, 50 to 80 cm in size. Layered gabbros in the hanging wall and the footwall are partially altered and abundantly veined by epidote, prehnite, laumontite and calcite veins. In the wall rocks, igneous plagioclase (An82±2%) is partially altered towards more albitic compositions (An75-81), and chlorite + tremolite partially replaces plagioclase and clinopyroxene. Clinopyroxene is moderately overgrown by Mg-hornblende. Whole rock mass change calculations show that the chlorite-rich fault rocks are enriched in Fe, Mn, H2O + CO2, Co, Cu, Zn, Ba, and U, but have lost significant amounts of Si, Ca, Na, Cr, Ni, Rb, Sr, Cs, light rare earth elements (LREE), Eu, and Pb. Gabbro clasts within the fault zone as well as altered rock from the immediate hanging wall show enrichments in Na, volatiles, Sr, Ba and U and depletions of Si, Ti, Al, Fe, Mn, Mg, Ca, Cu, Zn, Rb, Cs, LREE, and Pb. Chlorite thermometry suggests a formation temperature of 300–350 °C for the fault rock and based on the Si loss and solubility of silica in hydrothermal fluids the intensity of alteration requires a fluid to rock ratio of up to 900:1. Strontium isotope whole rock data of the fault rock yield 87Sr/86Sr ratios of 0.7043–0.7048, which is considerably more radiogenic than fresh layered gabbro from this locality (87Sr/86Sr = 0.7030–0.7033), and similar to black smoker hydrothermal signatures based on epidote, measured from epidote veins in the footwall and elsewhere in the ophiolite (87Sr/86Sr = 0.7043–0.7051). Altered gabbro clasts within the fault zone show similar values with 87Sr/86Sr ratios of ~0.7045–0.7050. In contrast, the hanging and footwall gabbros display values only slightly more radiogenic than fresh layered gabbro. The elevated strontium isotope composition of the fault rock and clasts together with the observed secondary mineral assemblages and calculated mass changes strongly supports the intense interaction with seawater-derived up-welling hydrothermal fluids, active during oceanic spreading. Assuming that such a fault zone is globally representative of faulting in the lower crust, an extrapolation of our results from mass change calculations to elemental fluxes, shows a significant contribution to the global hydrothermal budgets of Si, Ti, Fe, Mn, Mg, Ca, H2O, Cu, Zn, Sr and Cs.

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Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman. / Zihlmann, Barbara; Müller, Samuel; Coggon, Rosalind M. et al.
in: Lithos, Jahrgang 323, 15.12.2018, S. 103-124.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Zihlmann, B, Müller, S, Coggon, RM, Koepke, J, Garbe-Schönberg, D & Teagle, DAH 2018, 'Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman', Lithos, Jg. 323, S. 103-124. https://doi.org/10.1016/j.lithos.2018.09.008
Zihlmann, B., Müller, S., Coggon, R. M., Koepke, J., Garbe-Schönberg, D., & Teagle, D. A. H. (2018). Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman. Lithos, 323, 103-124. https://doi.org/10.1016/j.lithos.2018.09.008
Zihlmann B, Müller S, Coggon RM, Koepke J, Garbe-Schönberg D, Teagle DAH. Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman. Lithos. 2018 Dez 15;323:103-124. Epub 2018 Sep 13. doi: 10.1016/j.lithos.2018.09.008
Zihlmann, Barbara ; Müller, Samuel ; Coggon, Rosalind M. et al. / Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman. in: Lithos. 2018 ; Jahrgang 323. S. 103-124.
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title = "Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman",
abstract = "Hydrothermal circulation is a key process for chemical and isotopic exchange between the solid Earth and oceans, and for the extraction of heat from newly accreted crust at mid-ocean ridges. However, due to a dearth of samples from intact oceanic crust, or continuous sample suites from ophiolites, there remain major shortcomings in our understanding of hydrothermal circulation in the oceanic crust, especially in the lower plutonic crust. In particular, it remains unknown whether fluid recharge and discharge occurs pervasively or if it is mainly channelled within discrete zones such as faults. Here, we describe a hydrothermally-altered fault zone that crops out in the Wadi Gideah in the layered gabbro section of the Samail ophiolite of Oman. A one metre thick normal fault comprising deformed chlorite ± epidote fault rock with disseminated chalcopyrite and pyrite, offsets gently dipping layered olivine gabbros. The chlorite-rich fault rocks surround strongly altered clasts of layered gabbro, 50 to 80 cm in size. Layered gabbros in the hanging wall and the footwall are partially altered and abundantly veined by epidote, prehnite, laumontite and calcite veins. In the wall rocks, igneous plagioclase (An82±2%) is partially altered towards more albitic compositions (An75-81), and chlorite + tremolite partially replaces plagioclase and clinopyroxene. Clinopyroxene is moderately overgrown by Mg-hornblende. Whole rock mass change calculations show that the chlorite-rich fault rocks are enriched in Fe, Mn, H2O + CO2, Co, Cu, Zn, Ba, and U, but have lost significant amounts of Si, Ca, Na, Cr, Ni, Rb, Sr, Cs, light rare earth elements (LREE), Eu, and Pb. Gabbro clasts within the fault zone as well as altered rock from the immediate hanging wall show enrichments in Na, volatiles, Sr, Ba and U and depletions of Si, Ti, Al, Fe, Mn, Mg, Ca, Cu, Zn, Rb, Cs, LREE, and Pb. Chlorite thermometry suggests a formation temperature of 300–350 °C for the fault rock and based on the Si loss and solubility of silica in hydrothermal fluids the intensity of alteration requires a fluid to rock ratio of up to 900:1. Strontium isotope whole rock data of the fault rock yield 87Sr/86Sr ratios of 0.7043–0.7048, which is considerably more radiogenic than fresh layered gabbro from this locality (87Sr/86Sr = 0.7030–0.7033), and similar to black smoker hydrothermal signatures based on epidote, measured from epidote veins in the footwall and elsewhere in the ophiolite (87Sr/86Sr = 0.7043–0.7051). Altered gabbro clasts within the fault zone show similar values with 87Sr/86Sr ratios of ~0.7045–0.7050. In contrast, the hanging and footwall gabbros display values only slightly more radiogenic than fresh layered gabbro. The elevated strontium isotope composition of the fault rock and clasts together with the observed secondary mineral assemblages and calculated mass changes strongly supports the intense interaction with seawater-derived up-welling hydrothermal fluids, active during oceanic spreading. Assuming that such a fault zone is globally representative of faulting in the lower crust, an extrapolation of our results from mass change calculations to elemental fluxes, shows a significant contribution to the global hydrothermal budgets of Si, Ti, Fe, Mn, Mg, Ca, H2O, Cu, Zn, Sr and Cs.",
keywords = "Faults, Global chemical flux, Hydrothermal alteration, Layered gabbro, Mass changes, Ocean crust, Oman ophiolite",
author = "Barbara Zihlmann and Samuel M{\"u}ller and Coggon, {Rosalind M.} and J{\"u}rgen Koepke and Dieter Garbe-Sch{\"o}nberg and Teagle, {Damon A.H.}",
note = "Funding information: [ We greatly acknowledge reviews from A. Barker and an anonymous reviewer that helped to improve this manuscript. T. M{\"u}ller is thanked for providing 87 Sr/ 86 Sr measurements of eight fresh layered gabbro samples. We thank M. Cooper, U. Westernstr{\"o}er, and K. Bremer for their assistance in the laboratories, A. Barker and L. Crispini for helpful thin section discussions, M. Schori and O. Beermann for fieldwork assistance and M. Harris for providing an early version of Fig. 11 . We thank the Public Authority for Mining of the Sultanate of Oman for allowing us to conduct field work. The research leading to these results received funding from the People Programme (Marie Curie Actions) of the European Union's Seventh Framework Programme FP7/2007-2013 under the REA grant agreement no. 608001, that supported BZ within the “Abyss” Initial Training Network. DT is supported by a Royal Society Wolfson Research Merit Award ( WM130051 ). Further essential funding was contributed to DGS by Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant No. 398945252 and to JK by Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant No. 270849521 . We greatly acknowledge reviews from A. Barker and an anonymous reviewer that helped to improve this manuscript. T. M?ller is thanked for providing 87Sr/86Sr measurements of eight fresh layered gabbro samples. We thank M. Cooper, U. Westernstr?er, and K. Bremer for their assistance in the laboratories, A. Barker and L. Crispini for helpful thin section discussions, M. Schori and O. Beermann for fieldwork assistance and M. Harris for providing Fig. 11. We thank the Public Authority for Mining of the Sultanate of Oman for allowing us to conduct field work. The research leading to these results received funding from the People Programme (Marie Curie Actions) of the European Union's Seventh Framework Programme FP7/2007-2013 under the REA grant agreement no. 608001, that supported BZ within the ?Abyss? Initial Training Network. DT is supported by a Royal Society Wolfson Research Merit Award (WM130051). Further essential funding was contributed to DGS under DFG research grant GA 1960/11-1. ",
year = "2018",
month = dec,
day = "15",
doi = "10.1016/j.lithos.2018.09.008",
language = "English",
volume = "323",
pages = "103--124",
journal = "Lithos",
issn = "0024-4937",
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Download

TY - JOUR

T1 - Hydrothermal fault zones in the lower oceanic crust: An example from Wadi Gideah, Samail ophiolite, Oman

AU - Zihlmann, Barbara

AU - Müller, Samuel

AU - Coggon, Rosalind M.

AU - Koepke, Jürgen

AU - Garbe-Schönberg, Dieter

AU - Teagle, Damon A.H.

N1 - Funding information: [ We greatly acknowledge reviews from A. Barker and an anonymous reviewer that helped to improve this manuscript. T. Müller is thanked for providing 87 Sr/ 86 Sr measurements of eight fresh layered gabbro samples. We thank M. Cooper, U. Westernströer, and K. Bremer for their assistance in the laboratories, A. Barker and L. Crispini for helpful thin section discussions, M. Schori and O. Beermann for fieldwork assistance and M. Harris for providing an early version of Fig. 11 . We thank the Public Authority for Mining of the Sultanate of Oman for allowing us to conduct field work. The research leading to these results received funding from the People Programme (Marie Curie Actions) of the European Union's Seventh Framework Programme FP7/2007-2013 under the REA grant agreement no. 608001, that supported BZ within the “Abyss” Initial Training Network. DT is supported by a Royal Society Wolfson Research Merit Award ( WM130051 ). Further essential funding was contributed to DGS by Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant No. 398945252 and to JK by Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant No. 270849521 . We greatly acknowledge reviews from A. Barker and an anonymous reviewer that helped to improve this manuscript. T. M?ller is thanked for providing 87Sr/86Sr measurements of eight fresh layered gabbro samples. We thank M. Cooper, U. Westernstr?er, and K. Bremer for their assistance in the laboratories, A. Barker and L. Crispini for helpful thin section discussions, M. Schori and O. Beermann for fieldwork assistance and M. Harris for providing Fig. 11. We thank the Public Authority for Mining of the Sultanate of Oman for allowing us to conduct field work. The research leading to these results received funding from the People Programme (Marie Curie Actions) of the European Union's Seventh Framework Programme FP7/2007-2013 under the REA grant agreement no. 608001, that supported BZ within the ?Abyss? Initial Training Network. DT is supported by a Royal Society Wolfson Research Merit Award (WM130051). Further essential funding was contributed to DGS under DFG research grant GA 1960/11-1.

PY - 2018/12/15

Y1 - 2018/12/15

N2 - Hydrothermal circulation is a key process for chemical and isotopic exchange between the solid Earth and oceans, and for the extraction of heat from newly accreted crust at mid-ocean ridges. However, due to a dearth of samples from intact oceanic crust, or continuous sample suites from ophiolites, there remain major shortcomings in our understanding of hydrothermal circulation in the oceanic crust, especially in the lower plutonic crust. In particular, it remains unknown whether fluid recharge and discharge occurs pervasively or if it is mainly channelled within discrete zones such as faults. Here, we describe a hydrothermally-altered fault zone that crops out in the Wadi Gideah in the layered gabbro section of the Samail ophiolite of Oman. A one metre thick normal fault comprising deformed chlorite ± epidote fault rock with disseminated chalcopyrite and pyrite, offsets gently dipping layered olivine gabbros. The chlorite-rich fault rocks surround strongly altered clasts of layered gabbro, 50 to 80 cm in size. Layered gabbros in the hanging wall and the footwall are partially altered and abundantly veined by epidote, prehnite, laumontite and calcite veins. In the wall rocks, igneous plagioclase (An82±2%) is partially altered towards more albitic compositions (An75-81), and chlorite + tremolite partially replaces plagioclase and clinopyroxene. Clinopyroxene is moderately overgrown by Mg-hornblende. Whole rock mass change calculations show that the chlorite-rich fault rocks are enriched in Fe, Mn, H2O + CO2, Co, Cu, Zn, Ba, and U, but have lost significant amounts of Si, Ca, Na, Cr, Ni, Rb, Sr, Cs, light rare earth elements (LREE), Eu, and Pb. Gabbro clasts within the fault zone as well as altered rock from the immediate hanging wall show enrichments in Na, volatiles, Sr, Ba and U and depletions of Si, Ti, Al, Fe, Mn, Mg, Ca, Cu, Zn, Rb, Cs, LREE, and Pb. Chlorite thermometry suggests a formation temperature of 300–350 °C for the fault rock and based on the Si loss and solubility of silica in hydrothermal fluids the intensity of alteration requires a fluid to rock ratio of up to 900:1. Strontium isotope whole rock data of the fault rock yield 87Sr/86Sr ratios of 0.7043–0.7048, which is considerably more radiogenic than fresh layered gabbro from this locality (87Sr/86Sr = 0.7030–0.7033), and similar to black smoker hydrothermal signatures based on epidote, measured from epidote veins in the footwall and elsewhere in the ophiolite (87Sr/86Sr = 0.7043–0.7051). Altered gabbro clasts within the fault zone show similar values with 87Sr/86Sr ratios of ~0.7045–0.7050. In contrast, the hanging and footwall gabbros display values only slightly more radiogenic than fresh layered gabbro. The elevated strontium isotope composition of the fault rock and clasts together with the observed secondary mineral assemblages and calculated mass changes strongly supports the intense interaction with seawater-derived up-welling hydrothermal fluids, active during oceanic spreading. Assuming that such a fault zone is globally representative of faulting in the lower crust, an extrapolation of our results from mass change calculations to elemental fluxes, shows a significant contribution to the global hydrothermal budgets of Si, Ti, Fe, Mn, Mg, Ca, H2O, Cu, Zn, Sr and Cs.

AB - Hydrothermal circulation is a key process for chemical and isotopic exchange between the solid Earth and oceans, and for the extraction of heat from newly accreted crust at mid-ocean ridges. However, due to a dearth of samples from intact oceanic crust, or continuous sample suites from ophiolites, there remain major shortcomings in our understanding of hydrothermal circulation in the oceanic crust, especially in the lower plutonic crust. In particular, it remains unknown whether fluid recharge and discharge occurs pervasively or if it is mainly channelled within discrete zones such as faults. Here, we describe a hydrothermally-altered fault zone that crops out in the Wadi Gideah in the layered gabbro section of the Samail ophiolite of Oman. A one metre thick normal fault comprising deformed chlorite ± epidote fault rock with disseminated chalcopyrite and pyrite, offsets gently dipping layered olivine gabbros. The chlorite-rich fault rocks surround strongly altered clasts of layered gabbro, 50 to 80 cm in size. Layered gabbros in the hanging wall and the footwall are partially altered and abundantly veined by epidote, prehnite, laumontite and calcite veins. In the wall rocks, igneous plagioclase (An82±2%) is partially altered towards more albitic compositions (An75-81), and chlorite + tremolite partially replaces plagioclase and clinopyroxene. Clinopyroxene is moderately overgrown by Mg-hornblende. Whole rock mass change calculations show that the chlorite-rich fault rocks are enriched in Fe, Mn, H2O + CO2, Co, Cu, Zn, Ba, and U, but have lost significant amounts of Si, Ca, Na, Cr, Ni, Rb, Sr, Cs, light rare earth elements (LREE), Eu, and Pb. Gabbro clasts within the fault zone as well as altered rock from the immediate hanging wall show enrichments in Na, volatiles, Sr, Ba and U and depletions of Si, Ti, Al, Fe, Mn, Mg, Ca, Cu, Zn, Rb, Cs, LREE, and Pb. Chlorite thermometry suggests a formation temperature of 300–350 °C for the fault rock and based on the Si loss and solubility of silica in hydrothermal fluids the intensity of alteration requires a fluid to rock ratio of up to 900:1. Strontium isotope whole rock data of the fault rock yield 87Sr/86Sr ratios of 0.7043–0.7048, which is considerably more radiogenic than fresh layered gabbro from this locality (87Sr/86Sr = 0.7030–0.7033), and similar to black smoker hydrothermal signatures based on epidote, measured from epidote veins in the footwall and elsewhere in the ophiolite (87Sr/86Sr = 0.7043–0.7051). Altered gabbro clasts within the fault zone show similar values with 87Sr/86Sr ratios of ~0.7045–0.7050. In contrast, the hanging and footwall gabbros display values only slightly more radiogenic than fresh layered gabbro. The elevated strontium isotope composition of the fault rock and clasts together with the observed secondary mineral assemblages and calculated mass changes strongly supports the intense interaction with seawater-derived up-welling hydrothermal fluids, active during oceanic spreading. Assuming that such a fault zone is globally representative of faulting in the lower crust, an extrapolation of our results from mass change calculations to elemental fluxes, shows a significant contribution to the global hydrothermal budgets of Si, Ti, Fe, Mn, Mg, Ca, H2O, Cu, Zn, Sr and Cs.

KW - Faults

KW - Global chemical flux

KW - Hydrothermal alteration

KW - Layered gabbro

KW - Mass changes

KW - Ocean crust

KW - Oman ophiolite

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DO - 10.1016/j.lithos.2018.09.008

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EP - 124

JO - Lithos

JF - Lithos

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