Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits
Ore forming processes involve the redistribution of heat, mass and momentum by a wide range of processes operating at different time and length scales. The fastest process at any given length scale tends to be the dominant control. Applying this principle to the array of physical processes that oper...
Main Authors: | , |
---|---|
Format: | Article |
Language: | English |
Published: |
Elsevier
2019-01-01
|
Series: | Geoscience Frontiers |
Online Access: | http://www.sciencedirect.com/science/article/pii/S1674987118300525 |
_version_ | 1797715826049024000 |
---|---|
author | Stephen J. Barnes Jesse C. Robertson |
author_facet | Stephen J. Barnes Jesse C. Robertson |
author_sort | Stephen J. Barnes |
collection | DOAJ |
description | Ore forming processes involve the redistribution of heat, mass and momentum by a wide range of processes operating at different time and length scales. The fastest process at any given length scale tends to be the dominant control. Applying this principle to the array of physical processes that operate within magma flow pathways leads to some key insights into the origins of magmatic Ni–Cu–PGE sulfide ore deposits. A high proportion of mineralised systems, including those in the super-giant Noril'sk-Talnakh camp, are formed in small conduit intrusions where assimilation of country rock has played a major role. Evidence of this process is reflected in the common association of sulfides with vari-textured contaminated host rocks containing xenoliths in varying stages of assimilation. Direct incorporation of S-bearing country rock xenoliths is likely to be the dominant mechanism for generating sulfide liquids in this setting. However, the processes of melting or dissolving these xenoliths is relatively slow compared with magma flow rates and, depending on xenolith lithology and the composition of the carrier magma, slow compared with settling and accumulation rates. Chemical equilibration between sulfide droplets and silicate magma is slower still, as is the process of dissolving sulfide liquid into initially undersaturated silicate magmas. Much of the transport and deposition of sulfide in the carrier magmas may occur while sulfide is still incorporated in the xenoliths, accounting for the common association of magmatic sulfide-matrix ore breccias and contaminated “taxitic” host rocks. Effective upgrading of so-formed sulfide liquids would require repetitive recycling by processes such as re-entrainment, back flow or gravity flow operating over the lifetime of the magma transport system as a whole. In contrast to mafic-hosted systems, komatiite-hosted ores only rarely show an association with externally-derived xenoliths, an observation which is partially due to the predominant formation of ores in lava flows rather than deep-seated intrusions, but also to the much shorter timescales of key component systems in hotter, less viscous magmas. Nonetheless, multiple cycles of deposition and entrainment are necessary to account for the metal contents of komatiite-hosted sulfides. More generally, the time and length scale approach introduced here may be of value in understanding other igneous processes as well as non-magmatic mineral systems. Keywords: Magmatic ore deposits, Assimilation, Intrusions, Nickel, Norilsk, Komatiites |
first_indexed | 2024-03-12T08:12:31Z |
format | Article |
id | doaj.art-14cb6ac968df497ea98f7f9fd3299e24 |
institution | Directory Open Access Journal |
issn | 1674-9871 |
language | English |
last_indexed | 2024-03-12T08:12:31Z |
publishDate | 2019-01-01 |
publisher | Elsevier |
record_format | Article |
series | Geoscience Frontiers |
spelling | doaj.art-14cb6ac968df497ea98f7f9fd3299e242023-09-02T19:03:57ZengElsevierGeoscience Frontiers1674-98712019-01-011017787Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore depositsStephen J. Barnes0Jesse C. Robertson1Corresponding author.; CSIRO Mineral Resources, Perth, AustraliaCSIRO Mineral Resources, Perth, AustraliaOre forming processes involve the redistribution of heat, mass and momentum by a wide range of processes operating at different time and length scales. The fastest process at any given length scale tends to be the dominant control. Applying this principle to the array of physical processes that operate within magma flow pathways leads to some key insights into the origins of magmatic Ni–Cu–PGE sulfide ore deposits. A high proportion of mineralised systems, including those in the super-giant Noril'sk-Talnakh camp, are formed in small conduit intrusions where assimilation of country rock has played a major role. Evidence of this process is reflected in the common association of sulfides with vari-textured contaminated host rocks containing xenoliths in varying stages of assimilation. Direct incorporation of S-bearing country rock xenoliths is likely to be the dominant mechanism for generating sulfide liquids in this setting. However, the processes of melting or dissolving these xenoliths is relatively slow compared with magma flow rates and, depending on xenolith lithology and the composition of the carrier magma, slow compared with settling and accumulation rates. Chemical equilibration between sulfide droplets and silicate magma is slower still, as is the process of dissolving sulfide liquid into initially undersaturated silicate magmas. Much of the transport and deposition of sulfide in the carrier magmas may occur while sulfide is still incorporated in the xenoliths, accounting for the common association of magmatic sulfide-matrix ore breccias and contaminated “taxitic” host rocks. Effective upgrading of so-formed sulfide liquids would require repetitive recycling by processes such as re-entrainment, back flow or gravity flow operating over the lifetime of the magma transport system as a whole. In contrast to mafic-hosted systems, komatiite-hosted ores only rarely show an association with externally-derived xenoliths, an observation which is partially due to the predominant formation of ores in lava flows rather than deep-seated intrusions, but also to the much shorter timescales of key component systems in hotter, less viscous magmas. Nonetheless, multiple cycles of deposition and entrainment are necessary to account for the metal contents of komatiite-hosted sulfides. More generally, the time and length scale approach introduced here may be of value in understanding other igneous processes as well as non-magmatic mineral systems. Keywords: Magmatic ore deposits, Assimilation, Intrusions, Nickel, Norilsk, Komatiiteshttp://www.sciencedirect.com/science/article/pii/S1674987118300525 |
spellingShingle | Stephen J. Barnes Jesse C. Robertson Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits Geoscience Frontiers |
title | Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits |
title_full | Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits |
title_fullStr | Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits |
title_full_unstemmed | Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits |
title_short | Time scales and length scales in magma flow pathways and the origin of magmatic Ni–Cu–PGE ore deposits |
title_sort | time scales and length scales in magma flow pathways and the origin of magmatic ni cu pge ore deposits |
url | http://www.sciencedirect.com/science/article/pii/S1674987118300525 |
work_keys_str_mv | AT stephenjbarnes timescalesandlengthscalesinmagmaflowpathwaysandtheoriginofmagmaticnicupgeoredeposits AT jessecrobertson timescalesandlengthscalesinmagmaflowpathwaysandtheoriginofmagmaticnicupgeoredeposits |