Geochemistry of the Furnace Magnetite Bed, Franklin, NewJersey, and the Relationship between Stratiform Iron Oxide Ores and StratiformZinc Oxide-Silicate Ores in the New Jersey Highlands

Skinner, Brian J.

doi:10.2113/gsecongeo.98.4.837

Cited by 7 publications

(1 citation statement)

References 89 publications

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“…However, many common zinc minerals today, including the carbonates aurichalcite [Zn 5 (CO 3 ) 2 (OH) 6 ], brianyoungite [Zn 3 CO 3 (OH) 4 ], hydrozincite [Zn 5 (CO 3 ) 2 (OH) 6 ], and smithsonite (ZnCO 3 ), are known only as secondary minerals formed in the oxidized zones of zinc-bearing deposits and thus may not have been present in the Hadean Eon. Therefore, it is possible that willemite would also have been unlikely to form as a skarn mineral, though willemite is included in table 1 as a possible regional metamorphic phase (Johnson and Skinner, 2003 O]; and more than 150 other zinc minerals are known only from the oxidized zones of secondary mineralization of zinc ore bodies. Consequently, while further work on the stability of zinc minerals under varying f O 2 -f S 2 -f CO 2 conditions is warranted, the great majority of zinc minerals have been excluded from the list of plausible Hadean mineral phases.…”

Section: Eon (Though Thermochemical Calculations Of the Redox Limitatmentioning

confidence: 99%

Paleomineralogy of the Hadean Eon: A preliminary species list

Hazen

2013

American Journal of Science

127

136

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The Hadean Eon, encompassing Earth's first 550 million years, was a time of significant planetary evolution. Nevertheless, prebiotic Earth's near-surface environment may have held no more than approximately 420 different rock-forming or accessory mineral species that were widely distributed and/or volumetrically significant. This relative Hadean mineralogical parsimony is a consequence of the limited modes of mineral paragenesis prior to 4 Ga compared to the last 3.0 billion years. Dominant Hadean Eon mineralizing processes include the evolution of a diverse suite of intrusive and extrusive igneous lithologies; hydrothermal alteration over a wide temperature range, notably serpentinization; authigenesis in marine sediments; diagenesis and low-grade metamorphism in near-surface environments; and impactrelated processes, including shock mineralization, creation of marginal hydrothermal zones, and excavation of deep metamorphosed terrains. On the other hand, the Hadean Eon may have been notably lacking in mineralization generated by plate tectonic processes, such as subduction zone volcanism and associated fluid-rock interactions, which result in massive sulfide deposition; convergent boundary orogenesis and consequent extensive granitoid-rooted continental landmasses; and the selection and concentration of incompatible elements in complex pegmatites, with hundreds of accompanying minerals. The dramatic mineralogical consequences of life are reflected in the absence of Hadean biomineralization; for example, the lack of extensive carbonate deposits and the associated restricted development of skarn and cave minerals prior to 4 Ga. Most importantly, it was not until after the establishment via photosynthesis of significant near-surface redox gradients that supergene alteration, redox-controlled ore deposition, and subaerial weathering in an oxidizing environment could diversify Earth's near-surface mineralogy. These post-Hadean processes may be responsible for over 4000 of the more than 4800 approved mineral species. Any scenario for life's origins that invokes minerals as agents of molecular synthesis, selection, protection, or organization must take into account the limited mineralogical repertoire of the time.

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Section: Eon (Though Thermochemical Calculations Of the Redox Limitatmentioning

confidence: 99%

Paleomineralogy of the Hadean Eon: A preliminary species list

Hazen

2013

American Journal of Science

127

136

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Sedimentary exhalative origin for magnetite deposits of the New Jersey Highlands

et al. 2017

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Stable Isotope and Petrologic Evidence for the Origin of Regional Marble-Hosted Magnetite Deposits and the Zinc Deposits at Franklin and Sterling Hill, New Jersey Highlands, United States

Peck¹,

Völkert²,

Mansur³

et al. 2009

Economic Geology

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Mesoproterozoic marble in the New Jersey Highlands hosts small magnetite deposits that occur in discrete groups along linear trends and are concentrated mainly in the western part of the region. Magnetite also forms a layer structurally beneath the Zn-Fe-Mn orebody at the Franklin mine. Marble host rocks are interlayered at Fe and Zn-Fe-Mn deposits with bimodal metavolcanic rocks (amphibolite and rhyolitic gneiss) that were deposited synchronously in a back-arc basin developed on the eastern margin of Laurentia between 1.3 and 1.25 Ga. Magnetite in the deposits ranges from massive to disseminated and is characterized by low Ti, variable Mn, and locally high S. Concentrations of As, V, Sb, and Zn are enriched in magnetite compared to marble host rocks and associated metavolcanic rocks. Carbon and oxygen isotope ratios of the marbles are consistent with water-rock interaction between the marble protolith and a mixture of igneous fluids and seawater. Regional geology, petrology, and isotope data indicate that Fe was introduced into the carbonate protolith as low-temperature Fe oxides and hydroxides via hydrothermal fluids discharged along basinal fracture zones on the sea floor. Related marble-hosted Zn-Fe-Mn deposits at Franklin and Sterling Hill contain the assemblage willemite + zincite + franklinite. Stable isotope compositions of the Zn deposits are consistent with alteration of host rocks by water-rich fluids, preserving protolith carbon isotope ratios. Stable isotope modeling suggests that Zn silicate + oxides or hydroxides represent an appropriate protolith for the high-grade Zn ores. Alteration of metavolcanic rocks at the Fe deposits, combined with the isotope data and other petrologic and geochemical evidence, document the presence of an extensive hydrothermal system of Grenville age centered in the western Highlands. Metals precipitating from this hydrothermal system were responsible for Fe in the marble-hosted magnetite deposits and Zn in the deposits at Franklin and Sterling Hill from the same or a related hydrothermal system. Underplating of the back arc by mafic magma provided the heat to melt the lower crust and drive the hydrothermal system, resulting in carbonate-hosted Fe and Zn ore deposits and associated bimodal volcanism.

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Geochemistry of the Furnace Magnetite Bed, Franklin, NewJersey, and the Relationship between Stratiform Iron Oxide Ores and StratiformZinc Oxide-Silicate Ores in the New Jersey Highlands

Cited by 7 publications

References 89 publications

Paleomineralogy of the Hadean Eon: A preliminary species list

Paleomineralogy of the Hadean Eon: A preliminary species list

Sedimentary exhalative origin for magnetite deposits of the New Jersey Highlands

Stable Isotope and Petrologic Evidence for the Origin of Regional Marble-Hosted Magnetite Deposits and the Zinc Deposits at Franklin and Sterling Hill, New Jersey Highlands, United States

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