SlideShare une entreprise Scribd logo

skarn deposits and their mode of formation

Télécharger en tant que PPTX, PDF
A
Adam Mbedzi

The document discusses skarn deposits, which form as a result of a magma body coming into contact with carbonate sedimentary rocks like limestone. Skarn deposits occur in the contact zone where hot fluids from the magma mix with and dissolve the carbonate rocks, forming new calcium-rich silicate minerals. Different types of skarn deposits are classified based on their dominant minerals and metals, such as iron, gold, tungsten, copper, and zinc skarns. Skarn deposits show zoning patterns with different mineral assemblages present in proximal and distal areas from the contact with the magma body.

1  sur  30
Skarn Deposits & Their Mode Of Formation SURNAME & INITIALS STUDENT NUMBER MBEDZI A. 11602169 RAMAREMISA H. 11606440 MAHOSI F. F. 11606113 MAKONDELELE T. P. 11606635 NOBELA V. 11594774
Introduction • Definition • Skarn refers to calcium-bearing silicates, silicate gangue or waste rock of any age often associated with sulfide deposits of different metals which consequently form as a result of a magma body coming in contact with carbonate sedimentary rocks such as limestone and dolostone. • Skarn deposits are mineral occurrences of economically valuable commodities that occur in the skarn environment or as a result of the process of skarnitisation i.e. the process at which the hot waters (fluids) carrying a plethora of metals mix in the contact zone, dissolve calcium-rich carbonate rocks, and convert the host carbonate rock to skarn deposits in a metamorphic known as “metasomatism”.
Evolution Of Skarn Deposits • The formation of skarn deposits is a dynamic process rather than a simple ideal model and this was also recognised by early skarn researchers e.g. Lindgren, 1902; Barrell, 1907; Goldschmidt, 1911; etc. • The term skarn was first published by Tornebohm where he stated “As subordinate layers in the feldspar-poor felsic volcanic rocks, there appear peculiar dark rocks which also are the ore’s host rock. These rocks are in the Persberg area denoted ‘skarn’, a word which likely can be used as a collective term for all such odd rocks occurring alongside the ores.” • Tornebohm then goes on to describe garnet-rich “brunskarn” (brown skarn) and pyroxene-rich “gronskarn” (green skarn). The skarns have gained recognition through their process of formation, and their complex mineralogical association including the ore deposits.
Cont. • Zharikov (1970) was perhaps the first to describe the systematic variations in skarn mineralogy among the major skarn classes. He used phase equilibria, mineral compatibilities, and compositional variations in solid solution series to describe and predict characteristic mineral assemblages for different skarn types. • His observations have been extended by Burt (1972) and Einaudi et al. (1981) to include a wide variety of deposit types and the mineralogical variations between types. • Even at this present world, skarn geology have remained interesting for both economic purposes and academic adventure. Therefore, this lays the basis of continual studies of skarn geology.
Mode Of Formation • Skarns are formed by mass chemical transportation and reactions between adjacent lithologies. • NB: Skarns need not be of igneous in origin i.e. two sedimentary layers can react to exchange metals during metamorphism e.g. banded iron formation and limestone to form skarns. • At widest use, skarn refers to metasomatised zones of wall rock adjacent to granites i.e. are intimately associated with granite intrusions.
Cont. Minerals Chemical Composition Orthoclase KAlSi3O8 Muscovite KAl2(AlSi3O10)(F, OH)2 (KF)2(Al2O3)3(SiO2)6(H2O) • This is because granitic magmas are more prone to generating late stage fluid rich silica with incompatible elements and halides because they are generally more potassic, oxidised and hydrous. • For example, the felsic minerals contained in the granite are evident to this phenomenon.
Cont. • Generally, skarns are formed at temperature ranges of roughly 400oC to 650oC and the pressure variables at depths of 1 to 10+ km.
Cont. • Interpretation of igneous texture may serve as clue to solve the depth at which not only intrusive rocks are emplaced, but also skarn is formed e.g. intrusive rocks with equigranular texture may indicate deep formation level. • Skarns may develop in areas where fissures intersect limestone as vein like structures but in deep skarn environment, rocks tends to deform in a ductile manner, rather than fracture i.e. intrusive contact with skarn at depth tends to be sub-parallel to joints. • In such occurrences, skarn is formed along bedding planes or clack of the sedimentary rocks resulting into “strata-bound” deposits.
Cont.
Classification of Skarns • Skarns are classified according to their origin, dominant mineralogy and other characteristics. • Skarns of igneous origin • Exoskarns - occur at and outside the granite which produced them, and are alterations of wall rocks. • Exoskarns constitute the majority of the world’s economic skarn deposits • Endoskarns - form within the granite mass itself, usually late in the intrusive emplacement and consist of cross-cutting stockworks, cooling joints and around the margins and uppermost sections of the granite itself. • Endoskarns are rarer, because fluids created by granite are usually formed in equilibrium with the minerals of the granite.
Cont.
Cont. • Endoskarns seem to form in granitic magmas which lose earlier more dilute hydrous fluids thereby creating a less dilute last spurt of exsolved fluids. • Boiling of the exsolved fluid is also considered important, as this creates a highly saline, incompatible-element-rich fluid phase and a highly volatile gas phase. • Skarns which are created by reaction between metamorphic-sedimentary layers are called chemical skarns, and also known as skarnoids. • Chemical skarns can form from isochemical metamorphism of thinly interlayered shale and carbonate units where metasomatic transfer of components between adjacent lithologies may occur on a small scale (perhaps centimetres).
Cont. • Skarns may be classified according to the dominant mineralogy: • Magnesium skarns (dominant mineral – forsterite). • Calcic skarns (dominant mineral – andradite). • This has gave rise to skarn deposits to be described according to their dominant economic metal or mineral present e.g. copper, iron, tungsten, zinc-lead, molybdenum, tin, talc etc. • Uncommon types of skarns are formed in contact with sulfidic or carbonaceous rocks such as black shales, graphite shales, banded iron formations and, occasionally, salt or evaporites. • In such types, fluids react less via chemical exchange of ions, because of the redox-oxidation potential of the wall rocks.
• The identification and classification of skarn deposits is based on their mineralogy. Although many skarn minerals are typical rock-forming minerals some are less abundant and most have compositional variations that can yield significant information about the environment of formation. Some minerals such as quartz and calcite are present in almost all skarns. • • Other minerals as humite, periclase, phlogopite, talc, serpentine and brucite are typical of magnesian skarns but are absent from most other skarn types. • Additionally there are many tin, boron, beryllium, and fluorine-bearing minerals which have very restricted but locally important parageneses. Skarn Mineralogy
Cont. • The main differences between amphiboles in different skarn types are variations in the amounts of Fe, Mg, Mn, Ca, Al, Na and K. Amphiboles in Au, W and Sn skarns are progressively more aluminous (actinolite- hastingsite-hornblende); amphiboles in Cu, Mo and Fe are progressively more iron rich in the tremolite-actinolite series; and amphiboles in zinc skarns are both Mn rich and Ca deficient, ranging from actinolite to dannemorite. • The minerals which are most useful for both classification and exploration are those, such as garnet, pyroxene and amphibole which are present in all skarn types and which show marked compositional variability. • For example, the manganiferous pyroxene, johannsenite is found almost exclusively in zinc skarns. Its presents without much further supporting information is definitive of the skarn type.
Skarn Zonation • In most skarns, there is a general zonation pattern of proximal garnet, distal pyroxene and vesuvianite (or a pyroxene such as wollastonite, bustamite or rhodonite) at the contact between skarn and marble. • In addition, individual skarn minerals may display systematic colour or compositional variations within the larger zonation pattern. For example, garnet is commonly dark red-brown in proximal occurrences, becomes lighter brown in more distal occurrences and is pale green near the marble front. • For some skarn systems, these zonation patterns can be “stretched out” for several kilometres and can provide a significant exploration guide
Cont. • Exoskarns show zoning of both silicate and ore minerals whereas endoskarn displays zonation resulting from the progressive addition (“back flushing”) of calcium and carbon dioxide into the igneous protolith.
Types of Skarn Deposits • Groupings of skarn deposits can be based on descriptive features such as protolith composition, rock type and dominant economic metal(s) as well as genetic features such as mechanism of fluid movement, temperature of formation and extent of magmatic involvement. Seven major skarn types (Fe, Au, W, Cu, Zn, Mo, and Sn) have received significant modern study and several others (including F, C, Pt, U and REE) are locally important. • Iron Skarn – The largest skarn deposits are the iron skarns. – They are mined for their magnetite content and although minor amounts of Cu, Co, Ni and Au may be present, iron is typically the only commodity recovered. – Many deposits are very large (>500 million tons, with>300 million tons contained Fe) and consist dominantly of magnetite, with only minor silicate gangue.
Cont. – In some cases, they contain significant amounts of copper and are transitional to more typical copper skarns. – They are formed when iron-rich plutons intrudes into limestone and volcanic wall rocks, and the available iron in solution tends to form magnetite rather than andradite or hedenbergile. • Gold skarns – Most high-grade gold skarns are associated reduced (ilmenite-bearing, Fe3+/Fe2+ <0.75), diorite-granodiorite plutons and dyke or sill complexes. – Such skarns are dominated by iron-rich pyroxene (typically >Hd50); proximal zones can contain abundant intermediate grandite garnet.
Cont. – Other common minerals include potassium feldspar, scapolite, vesuvianite, and apatite and high chlorine aluminous amphibole. – Distal or early zones contain biotite or potassium feldspar hornfels which extend for hundreds of meters beyond massive skarn. Due to clastic rich, carbonaceous nature of sedimentary rocks in these deposits, most skarn is relatively fine grained. – Some gold skarns contain unusual late prehnite or wollastonite retrograde alteration.
Cont. • Zinc skarns – zinc skarns occur in continental settings associated with either subduction or rifting. – They are mined for ores of zinc, lead and silver although zinc is usually dominant. They – Related igneous rocks span a wide range of compositions, from deep- seated batholiths to shallow dyke-sill complexes to surface volcanic extrusions. The common thread linking most zinc skarn ores is their occurrence distal to associated igneous rocks.
Cont. – Zinc skarns can be subdivided according to several criteria, including distance from magmatic source, temperature of formation, relative proportion of skarn and sulphide minerals and geometric shape of the ore body. – skarn minerals such as garnet and pyroxene is important because it indicates a restricted geochemical environment which is entirely distinct from other ore types such as Mississippi Valley-type deposits which also contain Zn-Pb-Ag ores but which absolutely lack skarn minerals. – Besides their Zn-Pb-Ag metal content, zinc skarns can be distinguished from other skarn types by their distinctive manganese and iron-rich mineralogy, by their occurrence along structural and lithological contacts and by the absence of significant metamorphic aureoles centred on the skarn.
Cont. – Almost all skarn minerals in these deposits can be enriched in manganese, including garnet, pyroxene, olivine, ilvite, pyroxenoid, amphibole, chlorire and serpentine. • Other types – Other types of skarn deposits includes: tungsten, copper, molybdenum and tin which can be found in association with the other types discussed above e.g. copper skarns are highly associated with iron or sometimes gold and zinc.
Conclusion • Whether one thinks of skarn as a rock type or as an alteration of previously existing rocks, skarns are mappable in the field and the basic map unit is defined by skarn mineralogy. A detailed map showing the distribution of skarn mineral phases will yield important information about the overall size, characteristics and genesis of a skarn system. Of course, the skarn mineralogy needs to be interpreted in terms of lithology, structure and timing. • Skarns are distinct from many other types of ore deposits. Almost all large skarn deposits are directly related to igneous rocks. One of the most fundamental controls of skarn mineralogy and metal content is the genesis and crystallisation history of the associated pluton. The late stage hydrothermal evolution of the pluton is mirrored by alteration and mineralization in the surrounding rocks. The reactivity of sedimentary rocks, particularly carbonate rocks, accounts for the abundance of skarns in most localities where magma is emplaced in the upper crust.
Any Questions
Back up • Example of world class copper skarn deposits. • Antamina is the world’s largest copper-zinc skarn deposit. – The Antamina copper-zinc mine is located in the Andes Mountains of Peru, approximately 285km north of Lima in the Department of Ancash. The elevation of the mine is 4,300m above sea level. – The Ok Tedi mine is located in the remote Star Mountains of Papua New Guinea’s Western Province. Ok Tedi Mining Limited (OTML) operates the mine. – skarns may occur in association with porphyry copper deposits. For example, the Twin Buttes in Arizona and Bingham Canyon in Utah host both porphyry and skarn deposits.
Cont. • Pine Creek Mine (tungsten), Inyo County, California, USA. • Avebury Mine (Nikel), Zeehan, Tasmania, (Australia).
Cont.
Cont.

Recommandé

SKARN DEPOSITS
SKARN DEPOSITSSKARN DEPOSITS
SKARN DEPOSITS
VICTOR OBI
 
Topic 3 ore forming processes and magmatic mineral deposits
Topic 3 ore forming processes and magmatic mineral depositsTopic 3 ore forming processes and magmatic mineral deposits
Topic 3 ore forming processes and magmatic mineral deposits
Geology Department, Faculty of Science, Tanta University
 
METAMORPHIC DIFFERENTIATION
METAMORPHIC DIFFERENTIATIONMETAMORPHIC DIFFERENTIATION
METAMORPHIC DIFFERENTIATION
GOPAL JI GUPTA
 
Textures of ore_minerals
Textures of ore_mineralsTextures of ore_minerals
Textures of ore_minerals
Jenny García González
 
Placer formation
Placer formationPlacer formation
Placer formation
Badal Mathur
 
Lamprophyre
LamprophyreLamprophyre
Lamprophyre
Pramoda Raj
 
volcanic exhalative process
volcanic exhalative processvolcanic exhalative process
volcanic exhalative process
Indrajith Udaya Kumara
 
ore of metamorphic affiliation economif geology
ore of metamorphic affiliation economif geology ore of metamorphic affiliation economif geology
ore of metamorphic affiliation economif geology
lucknow university
 

Recommandé

SKARN DEPOSITS
SKARN DEPOSITSSKARN DEPOSITS
SKARN DEPOSITS
VICTOR OBI
 
Topic 3 ore forming processes and magmatic mineral deposits
Topic 3 ore forming processes and magmatic mineral depositsTopic 3 ore forming processes and magmatic mineral deposits
Topic 3 ore forming processes and magmatic mineral deposits
Geology Department, Faculty of Science, Tanta University
 
METAMORPHIC DIFFERENTIATION
METAMORPHIC DIFFERENTIATIONMETAMORPHIC DIFFERENTIATION
METAMORPHIC DIFFERENTIATION
GOPAL JI GUPTA
 
Textures of ore_minerals
Textures of ore_mineralsTextures of ore_minerals
Textures of ore_minerals
Jenny García González
 
Placer formation
Placer formationPlacer formation
Placer formation
Badal Mathur
 
Lamprophyre
LamprophyreLamprophyre
Lamprophyre
Pramoda Raj
 
volcanic exhalative process
volcanic exhalative processvolcanic exhalative process
volcanic exhalative process
Indrajith Udaya Kumara
 
ore of metamorphic affiliation economif geology
ore of metamorphic affiliation economif geology ore of metamorphic affiliation economif geology
ore of metamorphic affiliation economif geology
lucknow university
 
magmatic deposits - economic geology
magmatic deposits - economic geologymagmatic deposits - economic geology
magmatic deposits - economic geology
Monikonkona Boruah
 
Ch 19 continental alkaline lecture
Ch 19 continental alkaline lectureCh 19 continental alkaline lecture
Ch 19 continental alkaline lecture
Raghav Gadgil
 
"Granites" Classification, Petrogenesis and Tectonic Descrimination
"Granites" Classification, Petrogenesis and Tectonic Descrimination"Granites" Classification, Petrogenesis and Tectonic Descrimination
"Granites" Classification, Petrogenesis and Tectonic Descrimination
Samir Kumar Barik
 
Ore deposits (contact metamorphism)
Ore deposits (contact metamorphism)Ore deposits (contact metamorphism)
Ore deposits (contact metamorphism)
knowledge
 
Wall Rock Alteration
Wall Rock AlterationWall Rock Alteration
Wall Rock Alteration
Adithya Shettar
 
Economic geology - Magmatic ore deposits_1
Economic geology - Magmatic ore deposits_1Economic geology - Magmatic ore deposits_1
Economic geology - Magmatic ore deposits_1
AbdelMonem Soltan
 
Ore forming process
Ore forming processOre forming process
Ore forming process
Abdul Bari Qanit
 
Ore bearing fluids
Ore bearing fluidsOre bearing fluids
Ore bearing fluids
Prof. A.Balasubramanian
 
Oxidation supergene enrichment
Oxidation supergene enrichmentOxidation supergene enrichment
Oxidation supergene enrichment
Vishnu Raayan
 
THE ORE-BEARING FLUIDS
THE ORE-BEARING FLUIDSTHE ORE-BEARING FLUIDS
THE ORE-BEARING FLUIDS
kunwar shruten chauhan
 
Anorthosite
Anorthosite Anorthosite
Anorthosite
Pramoda Raj
 
Economic geology - Mineral resources
Economic geology - Mineral resourcesEconomic geology - Mineral resources
Economic geology - Mineral resources
AbdelMonem Soltan
 
Mantle melting and Magmatic processes
Mantle melting and Magmatic processesMantle melting and Magmatic processes
Mantle melting and Magmatic processes
Ananya21Mittal
 
Ore deposits
Ore depositsOre deposits
Ore deposits
kunwar shruten chauhan
 
Kimberlites
KimberlitesKimberlites
Kimberlites
Pramoda Raj
 
Submarine Exhalative Deposits.pptx
Submarine Exhalative Deposits.pptxSubmarine Exhalative Deposits.pptx
Submarine Exhalative Deposits.pptx
Imposter7
 
Carbonatites
CarbonatitesCarbonatites
Carbonatites
Pramoda Raj
 
Types of metasomatism
Types of metasomatismTypes of metasomatism
Types of metasomatism
Chandan Kumar
 
Role of Trace Elements In Petrogenesis
Role of Trace Elements In Petrogenesis Role of Trace Elements In Petrogenesis
Role of Trace Elements In Petrogenesis
Gokul Anand
 
Classification of ore deposits
Classification of ore depositsClassification of ore deposits
Classification of ore deposits
Abdul Bari Qanit
 
Aire
AireAire
Aire
Isabella Tamayo Mejía
 
Complete Research[FULL VERSION]
Complete Research[FULL VERSION]Complete Research[FULL VERSION]
Complete Research[FULL VERSION]
Adam Mbedzi
 

Contenu connexe

Tendances

"Granites" Classification, Petrogenesis and Tectonic Descrimination
"Granites" Classification, Petrogenesis and Tectonic Descrimination"Granites" Classification, Petrogenesis and Tectonic Descrimination
"Granites" Classification, Petrogenesis and Tectonic Descrimination
Samir Kumar Barik
 
Role of Trace Elements In Petrogenesis
Role of Trace Elements In Petrogenesis Role of Trace Elements In Petrogenesis
Role of Trace Elements In Petrogenesis
Gokul Anand
 

Tendances (20)

magmatic deposits - economic geology
magmatic deposits - economic geologymagmatic deposits - economic geology
magmatic deposits - economic geology
 
Ch 19 continental alkaline lecture
Ch 19 continental alkaline lectureCh 19 continental alkaline lecture
Ch 19 continental alkaline lecture
 
"Granites" Classification, Petrogenesis and Tectonic Descrimination
"Granites" Classification, Petrogenesis and Tectonic Descrimination"Granites" Classification, Petrogenesis and Tectonic Descrimination
"Granites" Classification, Petrogenesis and Tectonic Descrimination
 
Ore deposits (contact metamorphism)
Ore deposits (contact metamorphism)Ore deposits (contact metamorphism)
Ore deposits (contact metamorphism)
 
Wall Rock Alteration
Wall Rock AlterationWall Rock Alteration
Wall Rock Alteration
 
Economic geology - Magmatic ore deposits_1
Economic geology - Magmatic ore deposits_1Economic geology - Magmatic ore deposits_1
Economic geology - Magmatic ore deposits_1
 
Ore forming process
Ore forming processOre forming process
Ore forming process
 
Ore bearing fluids
Ore bearing fluidsOre bearing fluids
Ore bearing fluids
 
Oxidation supergene enrichment
Oxidation supergene enrichmentOxidation supergene enrichment
Oxidation supergene enrichment
 
THE ORE-BEARING FLUIDS
THE ORE-BEARING FLUIDSTHE ORE-BEARING FLUIDS
THE ORE-BEARING FLUIDS
 
Anorthosite
Anorthosite Anorthosite
Anorthosite
 
Economic geology - Mineral resources
Economic geology - Mineral resourcesEconomic geology - Mineral resources
Economic geology - Mineral resources
 
Mantle melting and Magmatic processes
Mantle melting and Magmatic processesMantle melting and Magmatic processes
Mantle melting and Magmatic processes
 
Ore deposits
Ore depositsOre deposits
Ore deposits
 
Kimberlites
KimberlitesKimberlites
Kimberlites
 
Submarine Exhalative Deposits.pptx
Submarine Exhalative Deposits.pptxSubmarine Exhalative Deposits.pptx
Submarine Exhalative Deposits.pptx
 
Carbonatites
CarbonatitesCarbonatites
Carbonatites
 
Types of metasomatism
Types of metasomatismTypes of metasomatism
Types of metasomatism
 
Role of Trace Elements In Petrogenesis
Role of Trace Elements In Petrogenesis Role of Trace Elements In Petrogenesis
Role of Trace Elements In Petrogenesis
 
Classification of ore deposits
Classification of ore depositsClassification of ore deposits
Classification of ore deposits
 

En vedette

Complete Research[FULL VERSION]
Complete Research[FULL VERSION]Complete Research[FULL VERSION]
Complete Research[FULL VERSION]
Adam Mbedzi
 
Barberton Geological Field Mapping 2012
Barberton Geological Field Mapping 2012Barberton Geological Field Mapping 2012
Barberton Geological Field Mapping 2012
Adam Mbedzi
 
Syferfontein Dolomite Mine (Pty) Ltd
Syferfontein Dolomite Mine (Pty) LtdSyferfontein Dolomite Mine (Pty) Ltd
Syferfontein Dolomite Mine (Pty) Ltd
Adam Mbedzi
 
RoseWalshPortfolio_2015
RoseWalshPortfolio_2015RoseWalshPortfolio_2015
RoseWalshPortfolio_2015
Rose Walsh
 
Improving Health and Safety Regulatory Framework for the
Improving Health and Safety Regulatory Framework for theImproving Health and Safety Regulatory Framework for the
Improving Health and Safety Regulatory Framework for the
Adam Mbedzi
 

En vedette (17)

Aire
AireAire
Aire
 
Complete Research[FULL VERSION]
Complete Research[FULL VERSION]Complete Research[FULL VERSION]
Complete Research[FULL VERSION]
 
Barberton Geological Field Mapping 2012
Barberton Geological Field Mapping 2012Barberton Geological Field Mapping 2012
Barberton Geological Field Mapping 2012
 
Richard branson
Richard bransonRichard branson
Richard branson
 
Syferfontein Dolomite Mine (Pty) Ltd
Syferfontein Dolomite Mine (Pty) LtdSyferfontein Dolomite Mine (Pty) Ltd
Syferfontein Dolomite Mine (Pty) Ltd
 
World’s greatest leaders
World’s greatest leadersWorld’s greatest leaders
World’s greatest leaders
 
Community development blackboard module fall2016
Community development blackboard module fall2016Community development blackboard module fall2016
Community development blackboard module fall2016
 
Communication RA Fall Training 2015
Communication RA Fall Training 2015Communication RA Fall Training 2015
Communication RA Fall Training 2015
 
RoseWalshPortfolio_2015
RoseWalshPortfolio_2015RoseWalshPortfolio_2015
RoseWalshPortfolio_2015
 
Community Development Model
Community Development ModelCommunity Development Model
Community Development Model
 
Aire
AireAire
Aire
 
Improving Health and Safety Regulatory Framework for the
Improving Health and Safety Regulatory Framework for theImproving Health and Safety Regulatory Framework for the
Improving Health and Safety Regulatory Framework for the
 
Pilon fractures
Pilon fracturesPilon fractures
Pilon fractures
 
Title ix training 2016 fall
Title ix training 2016 fallTitle ix training 2016 fall
Title ix training 2016 fall
 
Contractor Marketing Math
Contractor Marketing MathContractor Marketing Math
Contractor Marketing Math
 
Final_Report
Final_ReportFinal_Report
Final_Report
 
Pilon fractures
Pilon fracturesPilon fractures
Pilon fractures
 

Similaire à skarn deposits and their mode of formation

Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...
Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...
Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...
Jean-Clement BEYEME ZOGO
 
Cobar_style_deposits_early_thoughts_MichaelOstrowski
Cobar_style_deposits_early_thoughts_MichaelOstrowskiCobar_style_deposits_early_thoughts_MichaelOstrowski
Cobar_style_deposits_early_thoughts_MichaelOstrowski
Michael Ostrowski
 

Similaire à skarn deposits and their mode of formation (20)

Vein deposits of tin and tungsten.pptx
Vein deposits of tin and tungsten.pptxVein deposits of tin and tungsten.pptx
Vein deposits of tin and tungsten.pptx
 
Geological criteria for ore prospecting.pptx
Geological criteria for ore prospecting.pptxGeological criteria for ore prospecting.pptx
Geological criteria for ore prospecting.pptx
 
Soil Forming Rocks and Minerals Classification
Soil Forming Rocks and Minerals ClassificationSoil Forming Rocks and Minerals Classification
Soil Forming Rocks and Minerals Classification
 
Attock cherrat field trip
Attock cherrat field tripAttock cherrat field trip
Attock cherrat field trip
 
GEOMORPHOLOGY-MINERALS AND ROCKS.pptx
GEOMORPHOLOGY-MINERALS AND ROCKS.pptxGEOMORPHOLOGY-MINERALS AND ROCKS.pptx
GEOMORPHOLOGY-MINERALS AND ROCKS.pptx
 
Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...
Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...
Jc beyeme zogo ppm presentation_stratigraphy of the hotazel iron formation in...
 
Mineral & energy resources
Mineral & energy resourcesMineral & energy resources
Mineral & energy resources
 
1. UNIT _ I Building Materials Stones.pptx
1. UNIT _ I Building Materials Stones.pptx1. UNIT _ I Building Materials Stones.pptx
1. UNIT _ I Building Materials Stones.pptx
 
Mineral & energy resources
Mineral & energy resourcesMineral & energy resources
Mineral & energy resources
 
lesson63typsofrocks-161207135212.pptx
lesson63typsofrocks-161207135212.pptxlesson63typsofrocks-161207135212.pptx
lesson63typsofrocks-161207135212.pptx
 
VMS_Deposit.pdf
VMS_Deposit.pdfVMS_Deposit.pdf
VMS_Deposit.pdf
 
Lesson 7 Earth and Earth Resources - Mineral Resources.pptx
Lesson 7 Earth and Earth Resources - Mineral Resources.pptxLesson 7 Earth and Earth Resources - Mineral Resources.pptx
Lesson 7 Earth and Earth Resources - Mineral Resources.pptx
 
Building Stones.pdf
Building Stones.pdfBuilding Stones.pdf
Building Stones.pdf
 
Building Stones
Building StonesBuilding Stones
Building Stones
 
3 TYPES OF ROCKS
3 TYPES OF ROCKS3 TYPES OF ROCKS
3 TYPES OF ROCKS
 
THE THREE TYPES OF ROCKS (Lets Rock N Roll)
THE THREE TYPES OF ROCKS (Lets Rock N Roll)THE THREE TYPES OF ROCKS (Lets Rock N Roll)
THE THREE TYPES OF ROCKS (Lets Rock N Roll)
 
Cobar_style_deposits_early_thoughts_MichaelOstrowski
Cobar_style_deposits_early_thoughts_MichaelOstrowskiCobar_style_deposits_early_thoughts_MichaelOstrowski
Cobar_style_deposits_early_thoughts_MichaelOstrowski
 
Ch 10 magma generation
Ch 10 magma generationCh 10 magma generation
Ch 10 magma generation
 
Economic geology - Sedimentary ore deposits
Economic geology - Sedimentary ore depositsEconomic geology - Sedimentary ore deposits
Economic geology - Sedimentary ore deposits
 
ON petrology-geology.ppt
ON petrology-geology.pptON petrology-geology.ppt
ON petrology-geology.ppt
 

skarn deposits and their mode of formation

  • 1. Skarn Deposits & Their Mode Of Formation SURNAME & INITIALS STUDENT NUMBER MBEDZI A. 11602169 RAMAREMISA H. 11606440 MAHOSI F. F. 11606113 MAKONDELELE T. P. 11606635 NOBELA V. 11594774
  • 2. Introduction • Definition • Skarn refers to calcium-bearing silicates, silicate gangue or waste rock of any age often associated with sulfide deposits of different metals which consequently form as a result of a magma body coming in contact with carbonate sedimentary rocks such as limestone and dolostone. • Skarn deposits are mineral occurrences of economically valuable commodities that occur in the skarn environment or as a result of the process of skarnitisation i.e. the process at which the hot waters (fluids) carrying a plethora of metals mix in the contact zone, dissolve calcium-rich carbonate rocks, and convert the host carbonate rock to skarn deposits in a metamorphic known as “metasomatism”.
  • 3. Evolution Of Skarn Deposits • The formation of skarn deposits is a dynamic process rather than a simple ideal model and this was also recognised by early skarn researchers e.g. Lindgren, 1902; Barrell, 1907; Goldschmidt, 1911; etc. • The term skarn was first published by Tornebohm where he stated “As subordinate layers in the feldspar-poor felsic volcanic rocks, there appear peculiar dark rocks which also are the ore’s host rock. These rocks are in the Persberg area denoted ‘skarn’, a word which likely can be used as a collective term for all such odd rocks occurring alongside the ores.” • Tornebohm then goes on to describe garnet-rich “brunskarn” (brown skarn) and pyroxene-rich “gronskarn” (green skarn). The skarns have gained recognition through their process of formation, and their complex mineralogical association including the ore deposits.
  • 4. Cont. • Zharikov (1970) was perhaps the first to describe the systematic variations in skarn mineralogy among the major skarn classes. He used phase equilibria, mineral compatibilities, and compositional variations in solid solution series to describe and predict characteristic mineral assemblages for different skarn types. • His observations have been extended by Burt (1972) and Einaudi et al. (1981) to include a wide variety of deposit types and the mineralogical variations between types. • Even at this present world, skarn geology have remained interesting for both economic purposes and academic adventure. Therefore, this lays the basis of continual studies of skarn geology.
  • 5. Mode Of Formation • Skarns are formed by mass chemical transportation and reactions between adjacent lithologies. • NB: Skarns need not be of igneous in origin i.e. two sedimentary layers can react to exchange metals during metamorphism e.g. banded iron formation and limestone to form skarns. • At widest use, skarn refers to metasomatised zones of wall rock adjacent to granites i.e. are intimately associated with granite intrusions.
  • 6. Cont. Minerals Chemical Composition Orthoclase KAlSi3O8 Muscovite KAl2(AlSi3O10)(F, OH)2 (KF)2(Al2O3)3(SiO2)6(H2O) • This is because granitic magmas are more prone to generating late stage fluid rich silica with incompatible elements and halides because they are generally more potassic, oxidised and hydrous. • For example, the felsic minerals contained in the granite are evident to this phenomenon.
  • 7. Cont. • Generally, skarns are formed at temperature ranges of roughly 400oC to 650oC and the pressure variables at depths of 1 to 10+ km.
  • 8. Cont. • Interpretation of igneous texture may serve as clue to solve the depth at which not only intrusive rocks are emplaced, but also skarn is formed e.g. intrusive rocks with equigranular texture may indicate deep formation level. • Skarns may develop in areas where fissures intersect limestone as vein like structures but in deep skarn environment, rocks tends to deform in a ductile manner, rather than fracture i.e. intrusive contact with skarn at depth tends to be sub-parallel to joints. • In such occurrences, skarn is formed along bedding planes or clack of the sedimentary rocks resulting into “strata-bound” deposits.
  • 10. Classification of Skarns • Skarns are classified according to their origin, dominant mineralogy and other characteristics. • Skarns of igneous origin • Exoskarns - occur at and outside the granite which produced them, and are alterations of wall rocks. • Exoskarns constitute the majority of the world’s economic skarn deposits • Endoskarns - form within the granite mass itself, usually late in the intrusive emplacement and consist of cross-cutting stockworks, cooling joints and around the margins and uppermost sections of the granite itself. • Endoskarns are rarer, because fluids created by granite are usually formed in equilibrium with the minerals of the granite.
  • 11. Cont.
  • 12. Cont. • Endoskarns seem to form in granitic magmas which lose earlier more dilute hydrous fluids thereby creating a less dilute last spurt of exsolved fluids. • Boiling of the exsolved fluid is also considered important, as this creates a highly saline, incompatible-element-rich fluid phase and a highly volatile gas phase. • Skarns which are created by reaction between metamorphic-sedimentary layers are called chemical skarns, and also known as skarnoids. • Chemical skarns can form from isochemical metamorphism of thinly interlayered shale and carbonate units where metasomatic transfer of components between adjacent lithologies may occur on a small scale (perhaps centimetres).
  • 13. Cont. • Skarns may be classified according to the dominant mineralogy: • Magnesium skarns (dominant mineral – forsterite). • Calcic skarns (dominant mineral – andradite). • This has gave rise to skarn deposits to be described according to their dominant economic metal or mineral present e.g. copper, iron, tungsten, zinc-lead, molybdenum, tin, talc etc. • Uncommon types of skarns are formed in contact with sulfidic or carbonaceous rocks such as black shales, graphite shales, banded iron formations and, occasionally, salt or evaporites. • In such types, fluids react less via chemical exchange of ions, because of the redox-oxidation potential of the wall rocks.
  • 14. • The identification and classification of skarn deposits is based on their mineralogy. Although many skarn minerals are typical rock-forming minerals some are less abundant and most have compositional variations that can yield significant information about the environment of formation. Some minerals such as quartz and calcite are present in almost all skarns. • • Other minerals as humite, periclase, phlogopite, talc, serpentine and brucite are typical of magnesian skarns but are absent from most other skarn types. • Additionally there are many tin, boron, beryllium, and fluorine-bearing minerals which have very restricted but locally important parageneses. Skarn Mineralogy
  • 15. Cont. • The main differences between amphiboles in different skarn types are variations in the amounts of Fe, Mg, Mn, Ca, Al, Na and K. Amphiboles in Au, W and Sn skarns are progressively more aluminous (actinolite- hastingsite-hornblende); amphiboles in Cu, Mo and Fe are progressively more iron rich in the tremolite-actinolite series; and amphiboles in zinc skarns are both Mn rich and Ca deficient, ranging from actinolite to dannemorite. • The minerals which are most useful for both classification and exploration are those, such as garnet, pyroxene and amphibole which are present in all skarn types and which show marked compositional variability. • For example, the manganiferous pyroxene, johannsenite is found almost exclusively in zinc skarns. Its presents without much further supporting information is definitive of the skarn type.
  • 16. Skarn Zonation • In most skarns, there is a general zonation pattern of proximal garnet, distal pyroxene and vesuvianite (or a pyroxene such as wollastonite, bustamite or rhodonite) at the contact between skarn and marble. • In addition, individual skarn minerals may display systematic colour or compositional variations within the larger zonation pattern. For example, garnet is commonly dark red-brown in proximal occurrences, becomes lighter brown in more distal occurrences and is pale green near the marble front. • For some skarn systems, these zonation patterns can be “stretched out” for several kilometres and can provide a significant exploration guide
  • 17. Cont. • Exoskarns show zoning of both silicate and ore minerals whereas endoskarn displays zonation resulting from the progressive addition (“back flushing”) of calcium and carbon dioxide into the igneous protolith.
  • 18.
  • 19. Types of Skarn Deposits • Groupings of skarn deposits can be based on descriptive features such as protolith composition, rock type and dominant economic metal(s) as well as genetic features such as mechanism of fluid movement, temperature of formation and extent of magmatic involvement. Seven major skarn types (Fe, Au, W, Cu, Zn, Mo, and Sn) have received significant modern study and several others (including F, C, Pt, U and REE) are locally important. • Iron Skarn – The largest skarn deposits are the iron skarns. – They are mined for their magnetite content and although minor amounts of Cu, Co, Ni and Au may be present, iron is typically the only commodity recovered. – Many deposits are very large (>500 million tons, with>300 million tons contained Fe) and consist dominantly of magnetite, with only minor silicate gangue.
  • 20. Cont. – In some cases, they contain significant amounts of copper and are transitional to more typical copper skarns. – They are formed when iron-rich plutons intrudes into limestone and volcanic wall rocks, and the available iron in solution tends to form magnetite rather than andradite or hedenbergile. • Gold skarns – Most high-grade gold skarns are associated reduced (ilmenite-bearing, Fe3+/Fe2+ <0.75), diorite-granodiorite plutons and dyke or sill complexes. – Such skarns are dominated by iron-rich pyroxene (typically >Hd50); proximal zones can contain abundant intermediate grandite garnet.
  • 21. Cont. – Other common minerals include potassium feldspar, scapolite, vesuvianite, and apatite and high chlorine aluminous amphibole. – Distal or early zones contain biotite or potassium feldspar hornfels which extend for hundreds of meters beyond massive skarn. Due to clastic rich, carbonaceous nature of sedimentary rocks in these deposits, most skarn is relatively fine grained. – Some gold skarns contain unusual late prehnite or wollastonite retrograde alteration.
  • 22. Cont. • Zinc skarns – zinc skarns occur in continental settings associated with either subduction or rifting. – They are mined for ores of zinc, lead and silver although zinc is usually dominant. They – Related igneous rocks span a wide range of compositions, from deep- seated batholiths to shallow dyke-sill complexes to surface volcanic extrusions. The common thread linking most zinc skarn ores is their occurrence distal to associated igneous rocks.
  • 23. Cont. – Zinc skarns can be subdivided according to several criteria, including distance from magmatic source, temperature of formation, relative proportion of skarn and sulphide minerals and geometric shape of the ore body. – skarn minerals such as garnet and pyroxene is important because it indicates a restricted geochemical environment which is entirely distinct from other ore types such as Mississippi Valley-type deposits which also contain Zn-Pb-Ag ores but which absolutely lack skarn minerals. – Besides their Zn-Pb-Ag metal content, zinc skarns can be distinguished from other skarn types by their distinctive manganese and iron-rich mineralogy, by their occurrence along structural and lithological contacts and by the absence of significant metamorphic aureoles centred on the skarn.
  • 24. Cont. – Almost all skarn minerals in these deposits can be enriched in manganese, including garnet, pyroxene, olivine, ilvite, pyroxenoid, amphibole, chlorire and serpentine. • Other types – Other types of skarn deposits includes: tungsten, copper, molybdenum and tin which can be found in association with the other types discussed above e.g. copper skarns are highly associated with iron or sometimes gold and zinc.
  • 25. Conclusion • Whether one thinks of skarn as a rock type or as an alteration of previously existing rocks, skarns are mappable in the field and the basic map unit is defined by skarn mineralogy. A detailed map showing the distribution of skarn mineral phases will yield important information about the overall size, characteristics and genesis of a skarn system. Of course, the skarn mineralogy needs to be interpreted in terms of lithology, structure and timing. • Skarns are distinct from many other types of ore deposits. Almost all large skarn deposits are directly related to igneous rocks. One of the most fundamental controls of skarn mineralogy and metal content is the genesis and crystallisation history of the associated pluton. The late stage hydrothermal evolution of the pluton is mirrored by alteration and mineralization in the surrounding rocks. The reactivity of sedimentary rocks, particularly carbonate rocks, accounts for the abundance of skarns in most localities where magma is emplaced in the upper crust.
  • 27. Back up • Example of world class copper skarn deposits. • Antamina is the world’s largest copper-zinc skarn deposit. – The Antamina copper-zinc mine is located in the Andes Mountains of Peru, approximately 285km north of Lima in the Department of Ancash. The elevation of the mine is 4,300m above sea level. – The Ok Tedi mine is located in the remote Star Mountains of Papua New Guinea’s Western Province. Ok Tedi Mining Limited (OTML) operates the mine. – skarns may occur in association with porphyry copper deposits. For example, the Twin Buttes in Arizona and Bingham Canyon in Utah host both porphyry and skarn deposits.
  • 28. Cont. • Pine Creek Mine (tungsten), Inyo County, California, USA. • Avebury Mine (Nikel), Zeehan, Tasmania, (Australia).
  • 29. Cont.
  • 30. Cont.