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Monakoff Mine, Cloncurry, Cloncurry Shire, Queensland, Australiai
Regional Level Types
Monakoff MineMine
CloncurryTown
Cloncurry ShireShire
QueenslandState
AustraliaCountry

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PhotosMapsSearch
Latitude & Longitude (WGS84):
20° 37' 30'' South , 140° 41' 17'' East
Latitude & Longitude (decimal):
-20.62500,140.68833
GeoHash:
G#: rhk49mq4e
GRN:
S14E93
Type:
Mine
KΓΆppen climate type:
BSh : Hot semi-arid (steppe) climate
Nearest Settlements:
PlacePopulationDistance
Cloncurry2,384 (2015)20.4km
Mindat Locality ID:
127294
Long-form identifier:
mindat:1:2:127294:2
GUID (UUID V4):
decb0cc3-7727-47d2-a2d3-1e329b2d22a2


The Mount Margaret mining operation exploits the Monakoff and E1 group of IOCG-style copper-gold deposits in the Cloncurry District of NW Queensland, Australia. Monakoff is located ~15 km ENE of Cloncurry, and is 20 km south of the Ernest Henry deposit. The E1 group of deposits are 22.5 km to the NNE of Monakoff and 8 km east of Ernest Henry.

The Mount Margaret ore is treated at the Ernest Henry mine (#Location: E1 20Β° 26' 36"S, 140Β° 47' 10"E; Monakoff 20Β° 37' 30"S, 140Β° 41' 20"E).

All of these deposits are hosted within the Eastern Succession of the Mount Isa Inlier, which consists of poly-deformed Palaeo- and Mesoproterozoic volcano-sedimentary Cover Sequences 2 and 3 (CS2 and 3), deposited between 1790 and 1690 Ma and from 1680 to 1610 Ma respectively.

For details of the regional setting and geology of the northeastern Cloncurry district, see the Ernest Henry record.

The upper 100 m of footwall lithologies comprise thinly (1 to 3 mm) intercalated magnetite-bearing muscovite pelites, psammopelites, and meta-dolerites of the uppermost Mount Norna Quartzite, overlain by massive porphyroblastic garnet-biotite schist (mostly of intrusive andesitic igneous origin, although the upper 3 to 5 m are vesicular), then a regionally persistent magnetite iron formation, and finally by strongly sheared metasediments immediately hosting the Monakoff West ore. The continuous, 1 to 2 m thick, prominently banded, quartz-magnetiteΒ±hematite iron formation can be traced through the whole prospect, occurring ~5 to 10 m above the top of the porphyroblastic garnet-biotite schist, hosted by pelitic metasediment. Banding varies from 1 to 2 mm 'wrinkly' lamination (possibly crenulations), to 0.5 cm interbands of quartz-barite, and spessartine-magnetite. The metadolerites are present as continuous sills, locally with angular contacts and variable epidote alteration, particularly adjacent to sediment contacts.

The hanging wall above the thin strip of sheared metasediment that hosts ore, commences with a 20 to 30 m thick interval of short strike-length metabasalts, minor iron formation, volcanic conglomerate, and breccia bearing clasts of limestone and meta-dolerites. A local pillow breccia outcrops close to the ore package near the centre of the deposit, while black carbonaceous limestone and stromatolitic cherts are also reported. More common rocks of the Toole Creek Volcanics occur above this complex, comprising massive medium- to coarse-grained meta-dolerite to gabbro in the west, and mixed meta-dolerite, meta-basalt, siliceous siltstone and minor iron formations in the east (Davidson et al., 2002).

The "ore package" is defined as the altered rocks adjacent to the ore, the ores themselves, and the overlying altered sediments and basaltic tuff, all of which young and dip to the south. Near-ore alteration in the footwall commences with porphyroblastic spessartine-biotite-quartz-plagioclase-chloritoid-tourmaline-biotite development within the meta-andesite, with idioblastic garnet occuring as disseminations or irregular bands localised on peperite zones. Locally, pink spessartine is overgrown by coarse-grained almandine + quartz, indicating peak metamorphism exceeded the almandine isograd. The timing of almandine stability is uncertain (Davidson et al., 2002).

The major enriched components of the ore compared to the country rocks are: S (>20% S), Ba (>25% BaO), F (~2 to 10% F), Fe (>10% FeO) and Ca (~10% CaO), with significant enrichments of minor element including economic Co, Cu, Au and Ag, plus, Pb, Sb, As, W, U, La, Ce and Zn. P2O5 abundances are low, with most ores containing only 0.2 to 0.4 wt.% P2O5. The highest values are systematically found in the iron formation, although no strong Fe-P correlation exists when all of the data is considered. La and Ce abundances are also very high, with values typically of >1000 ppm. Rather than apatite, the host phase for REE, U, and possibly P2O5, is monazite, which is common in ore intersections, and concentrates the LREE (Davidson et al., 2002).

The western Monakoff ore zone is enclosed by, and replaces, magnetite-bearing meta-siltstones, occurring at surface as a friable, but resistant, massive unit with variable black pyrolusite and malachite staining. At depth it occurs as a massive unit composed of barite, ponite (Fe-rhodochrosite), magnetite, chalcopyrite, pyrite, spessartine, fluorite Β±K-feldspar, sphalerite, galena, arsenopyrite, mackinawite, molybdenite, brannerite/davidite, pentlandite and linnaeite (Ashley, 1983).

The eastern Monakoff ore zone appears to mainly comprise replacement of a medium- to coarse-grained amphibolite, within a tight D2 fold adjacent to an unexposed east-west fault, represented at surface by buff-coloured silica, studded with randomly oriented crystals of coarse magnetite, magnetite-hematite, and hematite, that are consistent with faithful pseudomorphing of meta-gabbro. The silica is most likely a surficial regolith replacement product of carbonate. At depth this rock-type is a package of comparatively thin massive meta-dolerites and intercalated peperitised sediments, with the contact between the two lithologies more completely silicified, and an alteration zonation into the sediment of i). siderite-magnetite-pyrrhotite-chalcopyrite; ii). magnetite-siderite-quartz, to iii). biotite-quartz-magnetite over 1 m or less, while the adjacent dolerite contains incipient siderite alteration. It is interpreted that in the core of the fold, severe alteration affected the interior of the folded metadolerite as well as the sediment margins. The fluids, which were tightly focussed by the fold structure, produced wholesale replacement of dolerite, and a narrow west-plunging pipe with grades of 1.4 to 3.0% Cu, consisting of siderite-barite-magnetite-chalcopyrite, which is likely to have considerable depth extent (Davidson et al., 2002 and sources quoted therein).

Resource and reserve figures for the Mount Margaret Operation deposits were:
Monakoff + Monakoff East deposits (Xstrata, 2012):
Indicated resource - 2 Mt @ 1.4% Cu, 0.4 g/t Au
Inferred resource - 1 Mt @ 1.2% Cu, 0.4 g/t Au
Total resource - 3 Mt @ 1.33% Cu, 0.4 g/t Au
Nearly 3500 t of U3O8 is contained within these deposits. The average in-situ recoverable grade is ~112 ppm U3O8.


This Precambrian iron oxide - copper - gold deposit is located in the Mt Isa Inlier, northeast of Cloncurry.it formed in dilational zones in a shear zone in metasediments and metavolcanics. It is enriched in F, Ba, Co, Ag, Mn, REE, U, Pb, Sr and Zn.

Select Mineral List Type

Standard Detailed Gallery Strunz Chemical Elements

Mineral List


42 valid minerals.

Detailed Mineral List:

β“˜ Albite
Formula: Na(AlSi3O8)
β“˜ Alloclasite
Formula: Co1-xFexAsS
β“˜ Anglesite
Formula: PbSO4
β“˜ 'Apatite'
Formula: Ca5(PO4)3(Cl/F/OH)
β“˜ Arsenopyrite
Formula: FeAsS
β“˜ Azurite
Formula: Cu3(CO3)2(OH)2
References:
Per Vic Cloete.
β“˜ Baryte
Formula: BaSO4
β“˜ BastnΓ€site-(La)
Formula: La(CO3)F
β“˜ 'Biotite'
Formula: K(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
β“˜ Brochantite
Formula: Cu4(SO4)(OH)6
β“˜ Calcite
Formula: CaCO3
β“˜ Cerussite
Formula: PbCO3
β“˜ Chalcopyrite
Formula: CuFeS2
β“˜ 'Chlorite Group'
β“˜ Chrysocolla
Formula: Cu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
β“˜ 'Clinopyroxene Subgroup'
β“˜ Connellite
Formula: Cu19(SO4)(OH)32Cl4 · 3H2O
β“˜ Creedite
Formula: Ca3SO4Al2F8(OH)2 · 2H2O
β“˜ Duftite
Formula: PbCu(AsO4)(OH)
Description: Vanadium-rich
β“˜ Epidote
Formula: (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
References:
Per Vic Cloete.
β“˜ Fluorite
Formula: CaF2
β“˜ Galena
Formula: PbS
β“˜ 'Garnet Group'
Formula: X3Z2(SiO4)3
β“˜ Goethite
Formula: Ξ±-Fe3+O(OH)
β“˜ Gold
Formula: Au
β“˜ Gold var. Electrum
Formula: (Au,Ag)
β“˜ Hematite
Formula: Fe2O3
References:
Per Vic Cloete.
β“˜ Hydrozincite
Formula: Zn5(CO3)2(OH)6
β“˜ Jarosite
Formula: KFe3+3(SO4)2(OH)6
β“˜ 'K Feldspar'
β“˜ Libethenite
Formula: Cu2(PO4)(OH)
β“˜ Magnetite
Formula: Fe2+Fe3+2O4
β“˜ Malachite
Formula: Cu2(CO3)(OH)2
References:
Per Vic Cloete.
β“˜ 'Manganese Oxides'
β“˜ 'Meurigite'
β“˜ Mottramite
Formula: PbCu(VO4)(OH)
β“˜ Muscovite
Formula: KAl2(AlSi3O10)(OH)2
β“˜ Muscovite var. Sericite
Formula: KAl2(AlSi3O10)(OH)2
β“˜ Opal
Formula: SiO2 · nH2O
β“˜ Opal var. Opal-AN
Formula: SiO2 · nH2O
β“˜ Phurcalite
Formula: Ca2(UO2)3(PO4)2O2 · 7H2O
β“˜ Pseudomalachite
Formula: Cu5(PO4)2(OH)4
β“˜ Pyrite
Formula: FeS2
β“˜ Pyrrhotite
Formula: Fe1-xS
β“˜ Quartz
Formula: SiO2
β“˜ Quartz var. Chalcedony
Formula: SiO2
β“˜ Richetite
Formula: (Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
β“˜ Scorodite
Formula: Fe3+AsO4 · 2H2O
β“˜ Silver
Formula: Ag
β“˜ Spangolite
Formula: Cu6Al(SO4)(OH)12Cl · 3H2O
β“˜ Spessartine
Formula: Mn2+3Al2(SiO4)3
β“˜ Sphalerite
Formula: ZnS
β“˜ Torbernite
Formula: Cu(UO2)2(PO4)2 · 12H2O
References:
Per Vic Cloete.
β“˜ Treasurite
Formula: Ag7Pb6Bi15S32

Gallery:

Cu3(CO3)2(OH)2β“˜ Azurite
Cu4(SO4)(OH)6β“˜ Brochantite
Ca3SO4Al2F8(OH)2 · 2H2Oβ“˜ Creedite
CaF2β“˜ Fluorite
Cu2(CO3)(OH)2β“˜ Malachite
β“˜ 'Meurigite'
Ca2(UO2)3(PO4)2O2 · 7H2Oβ“˜ Phurcalite
Cu6Al(SO4)(OH)12Cl · 3H2Oβ“˜ Spangolite
Cu(UO2)2(PO4)2 · 12H2Oβ“˜ Torbernite

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
β“˜Silver1.AA.05Ag
β“˜Gold1.AA.05Au
β“˜var. Electrum1.AA.05(Au,Ag)
Group 2 - Sulphides and Sulfosalts
β“˜Sphalerite2.CB.05aZnS
β“˜Chalcopyrite2.CB.10aCuFeS2
β“˜Pyrrhotite2.CC.10Fe1-xS
β“˜Galena2.CD.10PbS
β“˜Pyrite2.EB.05aFeS2
β“˜Alloclasite2.EB.10bCo1-xFexAsS
β“˜Arsenopyrite2.EB.20FeAsS
β“˜Treasurite2.JB.40aAg7Pb6Bi15S32
Group 3 - Halides
β“˜Fluorite3.AB.25CaF2
β“˜Creedite3.CG.15Ca3SO4Al2F8(OH)2 Β· 2H2O
β“˜Connellite3.DA.25Cu19(SO4)(OH)32Cl4 Β· 3H2O
Group 4 - Oxides and Hydroxides
β“˜Goethite4.00.Ξ±-Fe3+O(OH)
β“˜Magnetite4.BB.05Fe2+Fe3+2O4
β“˜Hematite4.CB.05Fe2O3
β“˜Quartz4.DA.05SiO2
β“˜var. Chalcedony4.DA.05SiO2
β“˜Opal4.DA.10SiO2 Β· nH2O
β“˜var. Opal-AN4.DA.10SiO2 Β· nH2O
β“˜Richetite4.GB.15(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 Β· 41H2O
Group 5 - Nitrates and Carbonates
β“˜Calcite5.AB.05CaCO3
β“˜Cerussite5.AB.15PbCO3
β“˜Azurite5.BA.05Cu3(CO3)2(OH)2
β“˜Malachite5.BA.10Cu2(CO3)(OH)2
β“˜Hydrozincite5.BA.15Zn5(CO3)2(OH)6
β“˜BastnΓ€site-(La)5.BD.20aLa(CO3)F
Group 7 - Sulphates, Chromates, Molybdates and Tungstates
β“˜Anglesite7.AD.35PbSO4
β“˜Baryte7.AD.35BaSO4
β“˜Brochantite7.BB.25Cu4(SO4)(OH)6
β“˜Jarosite7.BC.10KFe3+3(SO4)2(OH)6
β“˜Spangolite7.DD.15Cu6Al(SO4)(OH)12Cl Β· 3H2O
Group 8 - Phosphates, Arsenates and Vanadates
β“˜Libethenite8.BB.30Cu2(PO4)(OH)
β“˜Pseudomalachite8.BD.05Cu5(PO4)2(OH)4
β“˜Duftite8.BH.35PbCu(AsO4)(OH)
β“˜Mottramite8.BH.40PbCu(VO4)(OH)
β“˜Scorodite8.CD.10Fe3+AsO4 Β· 2H2O
β“˜Torbernite8.EB.05Cu(UO2)2(PO4)2 Β· 12H2O
β“˜Phurcalite8.EC.35Ca2(UO2)3(PO4)2O2 Β· 7H2O
Group 9 - Silicates
β“˜Spessartine9.AD.25Mn2+3Al2(SiO4)3
β“˜Epidote9.BG.05a(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
β“˜Muscovite9.EC.15KAl2(AlSi3O10)(OH)2
β“˜var. Sericite9.EC.15KAl2(AlSi3O10)(OH)2
β“˜Chrysocolla9.ED.20Cu2-xAlx(H2-xSi2O5)(OH)4 Β· nH2O, x < 1
β“˜Albite9.FA.35Na(AlSi3O8)
Unclassified
β“˜'Chlorite Group'-
β“˜'Clinopyroxene Subgroup'-
β“˜'Biotite'-K(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
β“˜'K Feldspar'-
β“˜'Garnet Group'-X3Z2(SiO4)3
β“˜'Manganese Oxides'-
β“˜'Apatite'-Ca5(PO4)3(Cl/F/OH)
β“˜'Meurigite'-

List of minerals for each chemical element

HHydrogen
Hβ“˜ AzuriteCu3(CO3)2(OH)2
Hβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Hβ“˜ BrochantiteCu4(SO4)(OH)6
Hβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Hβ“˜ ConnelliteCu19(SO4)(OH)32Cl4 · 3H2O
Hβ“˜ CreediteCa3SO4Al2F8(OH)2 · 2H2O
Hβ“˜ DuftitePbCu(AsO4)(OH)
Hβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Hβ“˜ GoethiteΞ±-Fe3+O(OH)
Hβ“˜ Opal var. Opal-ANSiO2 · nH2O
Hβ“˜ HydrozinciteZn5(CO3)2(OH)6
Hβ“˜ JarositeKFe33+(SO4)2(OH)6
Hβ“˜ LibetheniteCu2(PO4)(OH)
Hβ“˜ MalachiteCu2(CO3)(OH)2
Hβ“˜ MottramitePbCu(VO4)(OH)
Hβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Hβ“˜ OpalSiO2 · nH2O
Hβ“˜ PhurcaliteCa2(UO2)3(PO4)2O2 · 7H2O
Hβ“˜ PseudomalachiteCu5(PO4)2(OH)4
Hβ“˜ Richetite(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
Hβ“˜ ScoroditeFe3+AsO4 · 2H2O
Hβ“˜ SpangoliteCu6Al(SO4)(OH)12Cl · 3H2O
Hβ“˜ TorberniteCu(UO2)2(PO4)2 · 12H2O
Hβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Hβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
CCarbon
Cβ“˜ AzuriteCu3(CO3)2(OH)2
Cβ“˜ BastnΓ€site-(La)La(CO3)F
Cβ“˜ CalciteCaCO3
Cβ“˜ CerussitePbCO3
Cβ“˜ HydrozinciteZn5(CO3)2(OH)6
Cβ“˜ MalachiteCu2(CO3)(OH)2
OOxygen
Oβ“˜ AlbiteNa(AlSi3O8)
Oβ“˜ AnglesitePbSO4
Oβ“˜ AzuriteCu3(CO3)2(OH)2
Oβ“˜ BaryteBaSO4
Oβ“˜ BastnΓ€site-(La)La(CO3)F
Oβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Oβ“˜ BrochantiteCu4(SO4)(OH)6
Oβ“˜ CalciteCaCO3
Oβ“˜ CerussitePbCO3
Oβ“˜ Quartz var. ChalcedonySiO2
Oβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Oβ“˜ ConnelliteCu19(SO4)(OH)32Cl4 · 3H2O
Oβ“˜ CreediteCa3SO4Al2F8(OH)2 · 2H2O
Oβ“˜ DuftitePbCu(AsO4)(OH)
Oβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Oβ“˜ GoethiteΞ±-Fe3+O(OH)
Oβ“˜ HematiteFe2O3
Oβ“˜ Opal var. Opal-ANSiO2 · nH2O
Oβ“˜ HydrozinciteZn5(CO3)2(OH)6
Oβ“˜ JarositeKFe33+(SO4)2(OH)6
Oβ“˜ LibetheniteCu2(PO4)(OH)
Oβ“˜ MagnetiteFe2+Fe23+O4
Oβ“˜ MalachiteCu2(CO3)(OH)2
Oβ“˜ MottramitePbCu(VO4)(OH)
Oβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Oβ“˜ OpalSiO2 · nH2O
Oβ“˜ PhurcaliteCa2(UO2)3(PO4)2O2 · 7H2O
Oβ“˜ PseudomalachiteCu5(PO4)2(OH)4
Oβ“˜ QuartzSiO2
Oβ“˜ Richetite(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
Oβ“˜ ScoroditeFe3+AsO4 · 2H2O
Oβ“˜ SpangoliteCu6Al(SO4)(OH)12Cl · 3H2O
Oβ“˜ SpessartineMn32+Al2(SiO4)3
Oβ“˜ TorberniteCu(UO2)2(PO4)2 · 12H2O
Oβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Oβ“˜ Garnet GroupX3Z2(SiO4)3
Oβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
FFluorine
Fβ“˜ BastnΓ€site-(La)La(CO3)F
Fβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Fβ“˜ CreediteCa3SO4Al2F8(OH)2 · 2H2O
Fβ“˜ FluoriteCaF2
Fβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
NaSodium
Naβ“˜ AlbiteNa(AlSi3O8)
MgMagnesium
Mgβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Mgβ“˜ Richetite(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
AlAluminium
Alβ“˜ AlbiteNa(AlSi3O8)
Alβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Alβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Alβ“˜ CreediteCa3SO4Al2F8(OH)2 · 2H2O
Alβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Alβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Alβ“˜ SpangoliteCu6Al(SO4)(OH)12Cl · 3H2O
Alβ“˜ SpessartineMn32+Al2(SiO4)3
Alβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
SiSilicon
Siβ“˜ AlbiteNa(AlSi3O8)
Siβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Siβ“˜ Quartz var. ChalcedonySiO2
Siβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Siβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Siβ“˜ Opal var. Opal-ANSiO2 · nH2O
Siβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Siβ“˜ OpalSiO2 · nH2O
Siβ“˜ QuartzSiO2
Siβ“˜ SpessartineMn32+Al2(SiO4)3
Siβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Siβ“˜ Garnet GroupX3Z2(SiO4)3
PPhosphorus
Pβ“˜ LibetheniteCu2(PO4)(OH)
Pβ“˜ PhurcaliteCa2(UO2)3(PO4)2O2 · 7H2O
Pβ“˜ PseudomalachiteCu5(PO4)2(OH)4
Pβ“˜ TorberniteCu(UO2)2(PO4)2 · 12H2O
Pβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
SSulfur
Sβ“˜ AlloclasiteCo1-xFexAsS
Sβ“˜ AnglesitePbSO4
Sβ“˜ ArsenopyriteFeAsS
Sβ“˜ BaryteBaSO4
Sβ“˜ BrochantiteCu4(SO4)(OH)6
Sβ“˜ ChalcopyriteCuFeS2
Sβ“˜ ConnelliteCu19(SO4)(OH)32Cl4 · 3H2O
Sβ“˜ CreediteCa3SO4Al2F8(OH)2 · 2H2O
Sβ“˜ GalenaPbS
Sβ“˜ JarositeKFe33+(SO4)2(OH)6
Sβ“˜ PyriteFeS2
Sβ“˜ PyrrhotiteFe1-xS
Sβ“˜ SpangoliteCu6Al(SO4)(OH)12Cl · 3H2O
Sβ“˜ SphaleriteZnS
Sβ“˜ TreasuriteAg7Pb6Bi15S32
ClChlorine
Clβ“˜ ConnelliteCu19(SO4)(OH)32Cl4 · 3H2O
Clβ“˜ SpangoliteCu6Al(SO4)(OH)12Cl · 3H2O
Clβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
KPotassium
Kβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Kβ“˜ JarositeKFe33+(SO4)2(OH)6
Kβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Kβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
CaCalcium
Caβ“˜ CalciteCaCO3
Caβ“˜ CreediteCa3SO4Al2F8(OH)2 · 2H2O
Caβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Caβ“˜ FluoriteCaF2
Caβ“˜ PhurcaliteCa2(UO2)3(PO4)2O2 · 7H2O
Caβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
TiTitanium
Tiβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
VVanadium
Vβ“˜ MottramitePbCu(VO4)(OH)
MnManganese
Mnβ“˜ SpessartineMn32+Al2(SiO4)3
FeIron
Feβ“˜ AlloclasiteCo1-xFexAsS
Feβ“˜ ArsenopyriteFeAsS
Feβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Feβ“˜ ChalcopyriteCuFeS2
Feβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Feβ“˜ GoethiteΞ±-Fe3+O(OH)
Feβ“˜ HematiteFe2O3
Feβ“˜ JarositeKFe33+(SO4)2(OH)6
Feβ“˜ MagnetiteFe2+Fe23+O4
Feβ“˜ PyriteFeS2
Feβ“˜ PyrrhotiteFe1-xS
Feβ“˜ Richetite(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
Feβ“˜ ScoroditeFe3+AsO4 · 2H2O
CoCobalt
Coβ“˜ AlloclasiteCo1-xFexAsS
CuCopper
Cuβ“˜ AzuriteCu3(CO3)2(OH)2
Cuβ“˜ BrochantiteCu4(SO4)(OH)6
Cuβ“˜ ChalcopyriteCuFeS2
Cuβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Cuβ“˜ ConnelliteCu19(SO4)(OH)32Cl4 · 3H2O
Cuβ“˜ DuftitePbCu(AsO4)(OH)
Cuβ“˜ LibetheniteCu2(PO4)(OH)
Cuβ“˜ MalachiteCu2(CO3)(OH)2
Cuβ“˜ MottramitePbCu(VO4)(OH)
Cuβ“˜ PseudomalachiteCu5(PO4)2(OH)4
Cuβ“˜ SpangoliteCu6Al(SO4)(OH)12Cl · 3H2O
Cuβ“˜ TorberniteCu(UO2)2(PO4)2 · 12H2O
ZnZinc
Znβ“˜ HydrozinciteZn5(CO3)2(OH)6
Znβ“˜ SphaleriteZnS
AsArsenic
Asβ“˜ AlloclasiteCo1-xFexAsS
Asβ“˜ ArsenopyriteFeAsS
Asβ“˜ DuftitePbCu(AsO4)(OH)
Asβ“˜ ScoroditeFe3+AsO4 · 2H2O
AgSilver
Agβ“˜ Gold var. Electrum(Au,Ag)
Agβ“˜ SilverAg
Agβ“˜ TreasuriteAg7Pb6Bi15S32
BaBarium
Baβ“˜ BaryteBaSO4
LaLanthanum
Laβ“˜ BastnΓ€site-(La)La(CO3)F
AuGold
Auβ“˜ Gold var. Electrum(Au,Ag)
Auβ“˜ GoldAu
PbLead
Pbβ“˜ AnglesitePbSO4
Pbβ“˜ CerussitePbCO3
Pbβ“˜ DuftitePbCu(AsO4)(OH)
Pbβ“˜ GalenaPbS
Pbβ“˜ MottramitePbCu(VO4)(OH)
Pbβ“˜ Richetite(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
Pbβ“˜ TreasuriteAg7Pb6Bi15S32
BiBismuth
Biβ“˜ TreasuriteAg7Pb6Bi15S32
UUranium
Uβ“˜ PhurcaliteCa2(UO2)3(PO4)2O2 · 7H2O
Uβ“˜ Richetite(Fe3+,Mg)Pb 8.6(UO2)36O36(OH)24 · 41H2O
Uβ“˜ TorberniteCu(UO2)2(PO4)2 · 12H2O

Other Regions, Features and Areas containing this locality

Australia
Australian PlateTectonic Plate

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References

Davidson, G.J., Davis, B.K. and Garner, A. (2002) Structural and geochemical constraints on the emplacement of the Monakoff oxide Cu-Au (-Co-U-REE-Ag-Zn-Pb) deposit, Mt Isa Inlier, Australia: in Porter, T.M. (Ed), 2002 Hydrothermal Iron Oxide Copper-Gold & Related Deposits: A Global Perspective, PGC Publishing, Adelaide, 2, 49-75.
www.portergeo.com.au (n.d.) http://www.portergeo.com.au/database/mineinfo.asp?mineid=mn674
Mineralogical and fluid characteristics of β€˜Monakoff-Style’ iron–oxide–copper–gold (IOCG) mineralisation in the Cloncurry Area, Queensland. in Abdurrahman, A., J. C. Ø. Andersen, and B. J. Williamson. "Meeting of the Geological Society’s Mineral Deposits Studies Group was held on the 2nd–4th January 2013 at the University of Leicester, UK." Applied Earth Science (Trans. Inst. Min. Metall. B) 121.4 (2012): 214.
Williams, M.R., Holwell, D.A., Lilly, R.M., Case, G.N.D. and McDonald, I. (2015) Mineralogical and fluid characteristics of the fluorite-rich Monakoff and E1 Cu-Au deposits, Cloncurry, Queensland, Australia. Ore Geology Reviews, 64, P.103.
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