Abstract
The recently discovered Offset Zone of the Mine Block Intrusion of the Lac des Iles Complex hosts palladium mineralization with unusually high Pd/Pt and Pd/Ir ratios in rocks that range from relatively unaltered norite to amphibolites and chlorite–actinolite–talc schist. Quantitative assessment of the effect of progressive alteration using mineral modes was done using total silicate H2O as a monitor of reaction progress (ξ = moles H2O added to form alteration minerals per 100 g of rock). Major mineral modal variations define three reaction regions: (1) ξ = 0.00–0.03, characterized by epidote/clinozoisite formation and some amphibole; (2) ξ = 0.03–0.23, characterized by formation of chlorite, amphibole, quartz muscovite/sericite, and calcite after plagioclase + pyroxene; and (3) ξ = 0.23–0.28, characterized by the formation of talc after earlier formed amphibole. Epidote occurs as an incongruent product from the destruction of plagioclase that is itself lost as the reaction proceeds. Pyroxene is altered at about twice the rate of plagioclase, resulting in pyroxene-rich protoliths to be more altered than those relatively enriched in plagioclase. Major elements variations largely reflect variations in the plagioclase/pyroxene ratio of the protolith, but compositional trends suggest a loss of Na with reaction progress. The base metal sulfides chalcopyrite, pyrrhotite, and pentlandite show decreasing abundance with reaction progress, forming pyrite (± magnetite) as an intermediate reaction product that also is lost as the reaction proceeds. Millerite is overall low but increases slightly. A more limited data set on the platinum-group minerals suggests that platinum-group element (PGE)-arsenides increase whereas PGE-sulfides and PGE-Bi-tellurides decrease with reaction progress. Assuming ore element concentrations in the protolith were constant and similar to relatively fresh norites, Pd increases modestly, by 5 %, whereas Pt decreases by about 65 % in the most altered rocks. Similarly, Cu, Au, and S decrease by 60, 82, and 94 %, respectively, in the most altered rocks. The antithetical behavior of Pd and the fact that Pd enrichment is not seen in altered dikes suggest that the Pd originally was enriched in the more melanocratic protoliths that are most extensively altered and that Pd also was lost in part. These results are consistent with the mineralization having been a high-temperature event that predated the amphibolite/greenschist alteration.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Barnes SJ (1993) Partitioning of the platinum group elements and gold between silicate and sulphide magmas in the Munni Munni Complex, Western Australia. Geochim Cosmochim Acta 57:1277–1290
Barnes S-J, Gomwe, TS (2010) Composition of the Lac des Iles Magma and Implications for the Origin of the Ore. In Abstracts, 11th Int Pt Symp 21–24 June 2010, Sudbury, Ontario, Canada. Ontario Geological Survey, Miscellaneous Release–Data 269.
Barnes S-J, Gomwe, TS (2011) The Pd Deposits of the Lac des Iles Complex, Northwestern Ontario. Rev Econ Geol 17:351–370
Bird DK, Brooks CK, Gannicott RA, Turner PA (1991) A gold-bearing horizon in the Skaergaard intrusion, East Greenland. Econ Geol 86:1083–1092
Brimhall GH (1979) Lithologic determination of mass transfer mechanisms of multiple stage porphyry copper mineralization at Butte, Montana: element recycling by hypogene leaching and enrichment of potassium-silicate protore. Econ Geol 74:556–589
Brügmann GE, Naldrett AJ, Macdonald AJ (1989) Magma mixing and constitutional zone-refining in the Lac-Des-Iles Complex, Ontario—genesis of platinum-group element mineralization. Econ Geol 84:1557–1573
Brügmann GE, Reischrnann T, Naldrett AJ, Sutcliffe RH (1997) Roots of an Archean volcanic arc complex; the Lac des Îles area in Ontario, Canada. Precambrian Res 81:223–239
Cabri LJ, Laflamme JHG (1979) Mineralogy of samples from the Lac des Iles Area, Ontario. CANMET report 79-27 20p
Dionne-Foster C (2002) Étude Minéragraphique et Pétrologique de la Zone Twilight, Complexe du Lac des Iles, Ontario: Unpub Projet de fin d’études, Université du Québec à Chicoutimi, 86 p.
Djon MLN, Barnes S-J (2012) Changes in sulfides and platinum-group minerals with the degree of alteration in the Roby, Twilight, and High Grade Zones of the Lac des Iles Complex, Ontario. Canada Miner Deposita (online). doi:10.1007/s00126-012-0401-z
Dunning GR (1979) The geology and platinum-group mineralization of the Roby Zone, Lac des Îles Complex, Northwestern Ontario. M.S. thesis, Carlton University, 129 p
Duran CJ, Barnes S-J, Corkery JT (2013) Petrogenesis of massive sulphides from the Lac-des-Iles Palladium ore deposits, Western Ontario, Canada. In: Mineral deposit research for a high-tech world. Proceedings of the 12th Biennial SGA Meeting, 12–15 August 2013, Uppsala, Sweden. ISBN 978-91-7403-207-9 978-981 pp (extended abstract)
Ferry JM (1985) Hydrothermal alteration of Tertiary igneous rocks from the Isle of Skye, northwest Scotland. I. Gabbros. Contrib Mineral Petrol 91:264–282
Hanley JJ, Gladney ER (2011) The presence of carbonic-dominant volatiles during the crystallization of sulfide-bearing mafic pegmatites in the North Roby Zone, Lac des Iles Complex, Ontario. Econ Geol 106:33–54
Hinchey JG, Hattori KH (2005) Magmatic mineralization and hydrothermal enrichment of the High Grade Zone at the Lac des Iles palladium mine, northern Ontario, Canada. Miner Deposita 40:13–23
Hinchey JG, Hattori KH, Langne MJ (2005) Geology, petrology, and controls on PGE mineralization of the southern Roby and Twilight zones, Lac des Iles mine, Canada. Econ Geol 100:43–61
Kanitpanyacharoen W, Boudreau AE (2013) Sulfide-associated mineral assemblages in the Bushveld Complex, South Africa: platinum-group element enrichment by vapor refining by chloride–carbonate fluids. Miner Deposita 48:193–210
Lavigne MJ, Michaud MJ (2001) Geology of North American Palladium Ltd'.s Roby Zone Deposit, Lac des Iles. Explor Min Geol 10:1–17
Loney RA, Himmelberg GR (1992) Petrogenesis of the Pd-rich intrusion at Salt Chuck, Prince of Wales Island: an Early Paleozoic Alaskan-type ultramafic body. Can Min 30:1005–1022
McCallum ME, Loucks RR, Carlson RR, Cooley EF, Doerge TA (1976) Platinum metals associated with hydrothermal copper ores of the New Rambler Mine, Medicine Bow Mountains, Wyoming. Econ Geol 71:1429–1450
Naldrett AJ (2004) Magmatic sulphide deposits: geology, geochemistry and exploration. Springer Berlin 727 pp
Nozaka T, Fryer P (2011) Alteration of the oceanic lower crust at a slow-spreading axis: insights from vein-related zoned halos in olivine gabbro from Atlantis Massif, Mid-Atlantic Ridge. J Petrol 52:634–664
Percival JA, Williams HR (1989) Late Archean Quetico metasedimentary belt, Superior Province, Canada. Geology 17:23–25
Piña R, Gervilla F, Ortega L, Lunar R (2008) Mineralogy and geochemistry of platinum-group elements in the Aguablanca Ni–Cu deposit (SW Spain). Min Petrol 92:259–282
Prendergast MD, Wilson AH (1989) The Great Dyke of Zimbabwe II: mineralization and mineral deposits. In: Prendergast MD, Jones MJ (eds) Magmatic sulphides—the Zimbabwe volume. London Inst Mining Metallurgy 21–41 pp
Seyfried WE Jr (1987) Experimental and theoretical constraints on hydrothermal alteration processes at mid-ocean ridges. Annu Rev Earth Planet Sci 15:317–335
Somarin AK, Kissin SA, Heerema DD, Bihari DJ (2009) Hydrothermal alteration, fluid inclusion and stable isotope studies of the north Roby Zone, Lac des Iles PGE mine, Ontario, Canada. Resour Geol 59:107–120
Stone D, Lavigne MJ, Schnieders B, Scott J, Wagner D (2003) Regional geology of the Lac des Iles Area. Summary of field work and other activities open file report 6120, Ontario Geological Survey 15-11–15-25 pp
Sutcliffe RH (1989) Magma mixing in late Archean tonalitic and mafic rocks of the Lac Des Iles Area, Western Superior Province. Precambrian Res 44:81–101
Sweeny JM (1989) The geochemistry and origin of platinum group element mineralization of the hybrid zone, Lac des Iles Complex, Northwestern Ontario. M.Sc. thesis, University of Western Ontario, London, Ontario, 185 pp
Talkington RW, Watkinson DH (1984) Trends in the distribution of the precious metals in the Lac-Des-Iles Complex, Northwestern Ontario. Can Min 22:125–136
Watkinson DH, Dunning GR (1979) Geology and platinum-group mineralization, Lac des Iles complex, northwestern Ontario. Can Min 17:453–462
Watkinson DH, Melling DR (1992) Hydrothermal origin of platinum-group mineralization in low-temperature copper sulfide-rich assemblages, Salt Chuck Intrusion, Alaska. Econ Geol 87:175–184
Watkinson DH, Lavigne MJ, Fox PE (2002) Magmatic-hydrothermal Cu- and Pd-rich deposits in gabbroic rocks from North America. In: Cabri LJ (ed) The geology, geochemistry, mineralogy and mineral beneficiation of platinum-group elements. Can Inst Min Metall 54, pp 299–320
Wood SA (2002) The aqueous geochemistry of the platinum group elements with applications to ore deposits. In: Cabri LJ (ed) The geology, geochemistry, mineralogy and mineral beneficiation of platinum-group elements. Can Inst Min Metall 54, pp 211–249
Acknowledgement
A. Boudreau would like to thank North American Platinum for their support of this project. This work was improved by the thoughtful reviews of Chusi Li and two anonymous reviewers, whose efforts are very much appreciated.
Author information
Authors and Affiliations
Corresponding author
Additional information
Editorial handling: C. Li
Electronic supplementary material
Below is the link to the electronic supplementary material.
ESM 1
(DOCX 28 kb)
Rights and permissions
About this article
Cite this article
Boudreau, A., Djon, L., Tchalikian, A. et al. The Lac Des Iles Palladium Deposit, Ontario, Canada part I. The effect of variable alteration on the Offset Zone. Miner Deposita 49, 625–654 (2014). https://doi.org/10.1007/s00126-014-0510-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00126-014-0510-y