Controls on the Formation of Komatiite-Associated Nickel-Copper Sulfide Deposits

Lesher, C. Michael; Groves, David

doi:10.1007/978-3-642-70902-9_4

Cited by 73 publications

(68 citation statements)

References 39 publications

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“…These can be feeder tubes or channels within extensive komatiite lava flow fields (Lesher 1989;Barnes 2006) (Fig. 2A), or feeders to large igneous province magmatism in the form of sill-dike combinations (Fig.…”

Section: The Form Of Ore-hosting Magma Bodiesmentioning

confidence: 99%

“…Addition of external S is regarded as the dominant process in the formation of all komatiite-hosted ores (Lesher, 1989), and in the great majority of intrusion-hosted deposits (Ripley and Li 2013). Crustal rocks can have S isotope and S/Se ratio signatures that are usually very distinct from mantle S, such that these signatures can be used as tracers for orebody S sources.…”

Section: Incorporation Of External Crustal S Giving Rise To Sulfide mentioning

confidence: 99%

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Magmatic Sulfide Ore Deposits

Barnes¹,

Holwell

2017

ELEMENTS

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Magmatic sulfide ore deposits are products of natural smelting: concentration of elements from silicate magmas (slags) by immiscible sulfide liquid (matte). Deposits occupy a spectrum from accumulated pools of matte within small igneous intrusions or lava flows, forming orebodies mined primarily for Ni and Cu, to stratiform layers of weakly disseminated sulfides, mined for platinum group elements, within large maficultramafic intrusions. One of the world's most valuable deposits, the Platreef in the Bushveld Complex in South Africa, has aspects of both of these end members. Natural matte compositions vary widely between and within deposits, controlled largely by the relative volumes of matte and slag that interact with one another.

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Section: The Form Of Ore-hosting Magma Bodiesmentioning

confidence: 99%

Section: Incorporation Of External Crustal S Giving Rise To Sulfide mentioning

confidence: 99%

Magmatic Sulfide Ore Deposits

Barnes¹,

Holwell

2017

ELEMENTS

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“…If these primary magmas reached the surface they would erupt at temperatures not far from their 1-atm liquidus temperatures. Some high-flux magmas may become superheated during their ascent from their source to the surface [Lewis and Williams, 1973;Lesher and Groves, 1986], and these would erupt at temperatures above their liquidus. Most magmas, however, lose heat to their surroundings and partially crystallize; this is likely to be most problematic in low flux situations such as oceanic ridges, but it can also apply to intraplate occurrences.…”

Section: Magmatic Temperaturesmentioning

confidence: 99%

Temperatures in ambient mantle and plumes: Constraints from basalts, picrites, and komatiites

Herzberg

Asimow

Arndt

et al. 2007

Geochem Geophys Geosyst

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630

449

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International audienceSeveral methods have been developed to assess the thermal state of the mantle below oceanic ridges, islands, and plateaus, on the basis of the petrology and geochemistry of erupted lavas. One leads to the conclusion that mantle potential temperature (i.e., TP) of ambient mantle below oceanic ridges is 1430°C, the same as Hawaii. Another has ridges with a large range in ambient mantle potential temperature (i.e., TP = 1300–1570°C), comparable in some cases to hot spots (Klein and Langmuir, 1987; Langmuir et al., 1992). A third has uniformly low temperatures for ambient mantle below ridges, ∼1300°C, with localized 250°C anomalies associated with mantle plumes. All methods involve assumptions and uncertainties that we critically evaluate. A new evaluation is made of parental magma compositions that would crystallize olivines with the maximum forsterite contents observed in lava flows. These are generally in good agreement with primary magma compositions calculated using the mass balance method of Herzberg and O'Hara (2002), and differences reflect the well-known effects of fractional crystallization. Results of primary magma compositions we obtain for mid-ocean ridge basalts and various oceanic islands and plateaus generally favor the third type of model but with ambient mantle potential temperatures in the range 1280–1400°C and thermal anomalies that can be 200–300°C above this background. Our results are consistent with the plume model

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“…Assimilation of sedimentary materials could have occurred upstream, closer to the vent, where turbulent flow is more likely to take place. The immiscible sulfide ore magma may then have been carried away by the komatiite flow and locally concentrated where the flow became less turbulent, in the distal regions of the flow field (Lesher 1989). …”

Section: Timing Of Sulfide Saturationmentioning

confidence: 99%

Re Os ISOTOPIC STUDY OF KOMATIITIC VOLCANISM AND MAGMATIC SULFIDE FORMATION IN THE SOUTHERN ABITIBI GREENSTONE BELT, ONTARIO, CANADA

Lahaye

Barnes

Frick

et al. 2001

The Canadian Mineralogist

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We have investigated the Re-Os isotope geochemistry of 2.7-Ga metakomatiitic flows and associated Ni-Cu sulfide deposits from Alexo, Texmont and Hart in the Abitibi greenstone belt of Ontario in order to refine the thermal erosion model and evaluate the superimposed effects of metamorphism and hydrothermal alteration on ore environments and non-ore environments. Although the geochemical characteristics of these komatiites have led to the belief that these lavas were uncontaminated, radiogenic Os isotopic compositions (␥Os = +20.2 and +33.2) obtained from well-preserved komatiites and olivine separates suggest that the Alexo flow has been contaminated by crust-derived material. These data are compatible with the trace-element enrichment observed in melt inclusions trapped within olivine. Redistribution of Os and Re did occur at least at the mineral scale and most likely during the Grenville orogeny. Hydrothermal fluids were channeled along the contact between the komatiites and their basement, and were responsible for the remobilization of Re or Os (or both) within the sulfides at Alexo and Hart. Matrix and disseminated sulfides from Texmont are located within the pile of cumulates and seem to have escaped this localized alteration. Although the Abitibi sulfides have experienced various degrees of metamorphism (from prehnite-pumpellyite to low amphibolite facies), the initial Re-Os isotopic composition of the flows appears to have been preserved at the whole-rock scale. Re-Os isotopic heterogeneity of the Abitibi sulfides is best explained by variable R-factor of the sulfides. Re and Os concentrations and Os isotopic heterogeneity of the Abitibi sulfides are consistent with the current model of nickel sulfide formation, which implies that the assimilation of sulfidic sedimentary rocks was the trigger for sulfide saturation.Keywords: komatiite, Ni-Cu sulfide, rhenium-osmium, melt inclusion, laser ablation, Alexo, Hart, Texmont, Abitibi greenstone belt, Ontario. SOMMAIRENous avons étudié la géochimie isotopique Re-Os des coulées métakomatiitiques et des gisements de sulfures de Ni-Cu associés, Alexo, Texmont et Hart, dans la ceinture de roches vertes de l'Abitibi, en Ontario, mis en place il y a 2.7 milliards d'années, afin d'évaluer le modèle de l'érosion thermique et des effets surimposés du métamorphisme et l'altération hydrothermale dans les milieux près des gisements ou non. Bien que les caractéristiques géochimiques de ces komatiites ont mené à la conclusion que ces laves ne sont pas contaminées, les proportions d'Os radiogénique (␥Os = +20.2 et +33.

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Controls on the Formation of Komatiite-Associated Nickel-Copper Sulfide Deposits

Cited by 73 publications

References 39 publications

Magmatic Sulfide Ore Deposits

Magmatic Sulfide Ore Deposits

Temperatures in ambient mantle and plumes: Constraints from basalts, picrites, and komatiites

Re Os ISOTOPIC STUDY OF KOMATIITIC VOLCANISM AND MAGMATIC SULFIDE FORMATION IN THE SOUTHERN ABITIBI GREENSTONE BELT, ONTARIO, CANADA

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