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UNIVERSITY OF GOTHENBURG Department of Earth Sciences Geovetarcentrum/Earth Science Centre Brucite mineralization in a hydrothermally altered carbonate system, in the marble of Gåsgruvan Bergslagen area, central Sweden Andreas Wennerström ISSN 1400-3821 Mailing address Geovetarcentrum S 405 30 Göteborg B895 Master of Science (120 credits) thesis Göteborg 2015 Address Geovetarcentrum Guldhedsgatan 5A Telephone 031-786 19 56 Telefax 031-786 19 86 Geovetarcentrum Göteborg University S-405 30 Göteborg SWEDEN Brucite mineralization in a hydrothermally altered carbonate system, in the marble of Gåsgruvan Bergslagen area, central Sweden Andreas Wennerström, University of Gothenburg, Department of Earth Sciences; Geology, Box 460, SE-405 30 Gothenburg. Abstract Brucite mineralization has long been encountered in the marbles and limestones of Bergslagen. They were first discovered in the nineteenth century and have been explored in numerous carbonate rocks of Bergslagen to the present day. The carbonate rocks have a tendency to occur as lenses in the 1.9-1.8 Ga felsic metavolcanic rock. The calcitic marble of Gåsgruvan in Bergslagen is currently mined for industrial uses by SMA Mineral. Brucite mineralization can for them be a problem where the hydroxide member interferes with the pH-value, yielding a worse product. The objective of this thesis is to investigate the carbonate rocks of Gåsgruvan, trying to interpret and understand the brucite mineralization and how it relates to other minerals, hydrothermal alterations, and mafic intrusives. Six marble samples were collected in a southeast trending profile in Gåsgruvan, with varying content of brucite. The geochemistry of the samples was first analyzed with ICP-MS & ICP-AES, done by ALS geochemistry service. They were also analyzed with a scanning electron microscope at the University of Gothenburg, for subsequent correlation with mapped and XRF-analyzed drill cores, done by SMA Mineral. The studies show that brucite is furthermost related with hydrothermal magnesium metasomatic processes in contact metamorphism of dolomite and hydration of magnesium bearing minerals. Spinel and periclase indicate that the mafic intrusions increased the temperature locally from greenschist facies into amphibolite facies within the mine. These high-temperature minerals are an indication that the whole system resembles a >600°C metamorphic event. Access to magnesium in the calcitic marble is the controlling factor for brucite genesis, the magnesium enrichment was derived from the wall rock of granitic and mafic intrusions. Keywords: Brucite, Marble, Gåsgruvan, Bergslagen, SEM, REE, Metasomatic alteration Brucite mineralization in a hydrothermally altered carbonate system, in the marble of Gåsgruvan Bergslagen area, central Sweden Andreas Wennerström, University of Gothenburg, Department of Earth Sciences; Geology, Box 460, SE-405 30 Gothenburg. Sammanfattning Mineraliseringar av brucit har länge påträffats i Bergslagens marmor och kalkstenar. De upptäcktes för första gången på 1800-talet, och kom att påträffas i flera av Bergslagens karbonater i framtiden. Karbonaterna tenderer att ligga som linser i de 1.9–1,8 miljarder år gamla felsiska metavulkaniter. SMA mineral bryter en kalcitrik marmor i Gåsgruvan för industriellt bruk. För dem kan brucit vara ett problem då mineralets hydroxidgrupp påverkar pH-värdet, vilket resulterar i en sämre produkt. Arbetets syfte är att undersöka Gåsgruvans karbonater för att försöka tolka och förstå dess mineraliseringar av brucit och hur det relaterar sig gentemot andra mineral, hydrotermala omvandlingar och mafiska gångbergarter. Under detta arbete togs sex marmorstuffer i en sydostlig profil i Gåsgruvan med varierande innehåll av brucit. Provernas geokemi analyserades med ICP-MS & ICPAES av ALS. De analyserades även i ett svepelektronmikroskåp från Göteborgs Universitet, för att senare jämföras med karterade och XRF-analyserade borrtjärnor gjorda av SMA Mineral. Undersökningarna påvisar att brucit är ytterst relaterat till hydrotermal magnesiummetasomatos vid kontaktmetamorfos av dolomit och hydrering av magnesiumbärande mineral. Spinel och periklas indikerar att de mafiska intrusionerna lokalt höjt temperaturen från grönskifferfacies till amfibolitfacies i gruvan. Dessa högtempererade mineral indikerar att hela systemet liknar ett metamorft event från över 600°C. Tillgången till magnesium i den kalcitrika marmorn är den styrande faktorn för brucit genesis, vars anrikning härstammar från de granitiska och mafiska intrusionernas sidoberg. Nyckelord: Brucit, Marmor, Gåsgruvan, Bergslagen, SEM, REE, Metasomatiska omvandlingar Contents Introduction ............................................................................................................................... 1 Objectives.............................................................................................................................. 1 Background ........................................................................................................................... 2 Occurrence of Brucite ....................................................................................................... 2 Genesis of Brucite............................................................................................................. 2 Geological Background ............................................................................................................. 4 Regional Geology ................................................................................................................. 4 Tectonics of Bergslagen ................................................................................................... 7 Local geology & Site description.......................................................................................... 8 Mineralization ................................................................................................................. 10 Method..................................................................................................................................... 15 Sampling ............................................................................................................................. 15 Sample preparation ............................................................................................................. 17 Whole rock analysis preparation..................................................................................... 17 SEM rock slabs preparation ............................................................................................ 17 Analytical methods .................................................................................................................. 17 Whole rock chemistry analysis (ALS) ................................................................................ 17 ME-ICP06 Analysis ........................................................................................................ 17 ME-MS81 & ME-4ACD81 Analysis ............................................................................. 17 Scanning Electron Microscopy ........................................................................................... 17 XRF (Old boreholes, SMA) ................................................................................................ 18 Results & Interpretation .......................................................................................................... 18 Scanning Electron Microscope (SEM)................................................................................ 18 Sample GG10 SEM backscattered electron image (BSE) interpretation ........................ 18 Sample GG11 SEM backscattered electron image (BSE) interpretation ........................ 21 Sample GG12 SEM backscattered electron image (BSE) interpretation ........................ 24 Sample GG13 SEM backscattered electron image (BSE) interpretation ........................ 26 Sample GG14 SEM backscattered electron image (BSE) interpretation ........................ 28 Sample GG15 SEM backscattered electron image (BSE) interpretation ........................ 30 Geochemical Analysis, ALS ............................................................................................... 33 Variation Diagrams ......................................................................................................... 33 Rare Earth Elements ....................................................................................................... 35 XRF mapping, SMA Mineral ......................................................................................... 35 Discussion ............................................................................................................................... 38 Brucite ................................................................................................................................. 38 Metamorphism .................................................................................................................... 39 Hydrothermal Fluids ........................................................................................................... 40 Future studies ...................................................................................................................... 42 Conclusions ............................................................................................................................. 43 Acknowledgement ................................................................................................................... 44 Bibliography ............................................................................................................................ 45 Appendix 1: Middle Proterozoic rift system ........................................................................... 47 Appendix 2: ALS geochemistry whole rock analysis package ............................................... 48 Appendix 3: ALS geochemistry whole rock analysis data ...................................................... 49 Introduction Objectives The aim of this thesis is to investigate metamorphosed carbonate rocks which contain brucite, trying to perceive its genesis and relationship to other minerals and hydrothermal alterations. These objectives are pursued by making whole rock analysis of 6 carbonate samples containing brucite of a different grade in a profile towards metabasite, within the Gåsgruvan marble. These samples are furthermore analyzed in the SEM and compared with mapped and XRF-analyzed drill cores from Gåsgruvan for further interpretation. This thesis aim is to investigate and discuss following questions: Why do some carbonates contain brucite and how is it formed and related to other minerals? To what degree is it possible for a metabasite intrusion to raise the temperature from greenschist facies into amphibolite facies in marble, and can the observed mafic sills and dikes give rise to brucite mineralization? Why is there in general not much magnesium in the mine, even though enrichments of magnesium minerals are observed at specific locations? 1 Background Mined carbonate rock from Gåsgruvan is sent to OMYA on the Persberg Peninsula for the enrichment of calcite. Brucite is a problem for the floatation procedure in which they try to eliminate silicates to produce clean calcite powder for industrial use. The hydroxide member of brucite interferes with the pH value and the process balance, resulting in a poor yield of calcite. For other pulverized products, the brucite is not a problem, other than it yields a darker color for products which are supposed to be white. On the contrary, products used in agriculture can contain carbonates with brucite because higher magnesium content is helpful. Occurrence of Brucite Limestone and marble with disseminated brucite have been encountered many times within Bergslagen of Filipstad. The first person who observed these unusual rocks was L. J Igelström in 1858. He spotted them at three limestone mines (Igelström, 1858). A.E. Törnebohm remarked that he had found brucite-carrying limestone in Värmland in 1878 with isotropic cores of periclase. A Sjögren later found brucite in seven different mines in Bergslagen of Filipstad. Magnusson (1925) anticipated that the brucite genesis in limestone is associated with younger eruption magmas, such as the granite of Filipstad. At Gåsgruvan, one can observe that marble, rich in brucite appears in the southwestern part of the mine and that an embankment of dolomite is transcended into marble with brucite. The transition between the two is always very rapid, making the amount of brucite in the marble constant. This observation suggests that brucite mineralization in marble is related to isochemical contact metamorphism of dolomite (Magnusson, 1925). 1918 A.F Rogers found some occurrence of calcite-brucite rocks in California, which correspond well with those in Bergslagen of Filipstad. All of these occur near an erupted granitic or mafic contact in dolomite, Rogers also indicates a core of periclase in the brucite (Rogers, 1918). The term skarn is often mentioned in this thesis and refers to as calc-silicate mineralization formed by metasomatic processes in contact between a marble and an intrusive rock or from hydrothermal deposits. Genesis of Brucite Magnusson (1925) suggested that brucite in marble may be related to contact metamorphism of dolomite. In geological literature, brucite is considered the product of hydration of Mg-minerals in alkaline hydrothermal conditions, or in surface waters. There are a handful of scientists who during the past have interpreted the genesis and PT-conditions. An apparent phase diagram was produced by Bucher and Frey (2002) of a metamorphic contact aureole in dolomite marble at a constant pressure of 2 kbar. According to them, brucite may form by retrograde hydration of periclase (Reaction 1), where periclase first formed by thermal dedolomitization of dolomite (Reaction 2) in contact with an igneous body. Brucite could also be formed directly from dolomite, skipping the intermediate stage of periclase (Reaction 3): MgO+H2O→Mg(OH)2 Periclase CaMg(CO3)2→CaCO3+MgO+CO2 Dolomite (1) Brucite Calcite CaMg(CO3)2+H2O →CaCO3+ Mg(OH)2+CO2 Dolomite (2) Periclase Calcite Brucite 2 (3) Figure 1. T-XCO2 phase diagram in dolomite marbles containing excess dolomite and calcite at 2 kbar constant pressure (Bucher & Frey, 2002). It is also obvious from figure 1, that both periclase and brucite can only form from the interaction of dolomite-marble with an H2O-rich fluid (Bucher & Frey, 2002). Another remarkable way for brucite genesis is the hydrothermal alteration of forsterite from ultrabasic igneous rocks and pyrometasomatic contact aureoles established in dolomite. Steinberg was the first person who related serpentinization of forsterite to formation of brucite in 1960 (Ionescu, 1998), following (reaction 4): 4Mg2(SiO4) + 3H2O → Mg6[(OH)8|Si4O10] + 2Mg(OH)2 Forsterite Serpentine (4) Brucite Alteration of forsterite into serpentine minerals requires a low content of SiO2 in the hydrothermal fluids. The field of equilibrium limits for magnesium minerals concerning SiO2-factor at PH2O 1 kbar can be seen in figure 2 (Ionescu, 1998). 3 Figure 2. Limits of equilibrium between chrysotile (Serpentine), forsterite, brucite and periclase, at 1 kbar of PH2O (Ionescu, 1998). Brucite may additionally form by deposition from late postmagmatic hydrothermal solutions at 200°C and ground water which dissolves mg-carbonates from dolomites. There are further ways brucite genesis may take place, which are pretty much associated with hydration and metasomatism of additional magnesium minerals (Ionescu, 1998). Geological Background Regional Geology The Bergslagen region is very rich in various metallic mineral deposits, which is the southernmost mining district in Sweden. The region is one of many major igneous provinces of the Fennoscandian shield, which was formed, deformed and metamorphosed during the Svecokarelian orogeny between 1.9 and 1.8 Ga (Stephens et al. 2009). The mineral deposits correspond well with the felsic metavolcanic rocks in the northern and western part of Bergslagen (Figure 3). 4 Figure 3. Geologic bedrock map of Bergslagen area (Stephens et al. 2009). The region is dominated by submarine, felsic metavolcanic rocks with subaerial and submarine intervals, lavas and intermediate to basic volcanic rocks. The metavolcanic rocks were divided by Oen et al. (1982) into three groups, the lower-, medium- and upper leptite groups (Table 1). An age of 1.9 to 1.87 Ga has been determined by 40Ar/39Ar dating and the magmatic rocks are calc-alkaline (Löfgren, 1979). Hydrothermal solutions altered the unconsolidated volcanites through metasomatism into two major chemical groups, sodium- and potassium-rich leptite (Griffin & Helvaci, 1983). Limestone and sedimentary deposits occur at some places in the metavolcanic rocks, where they appear as layers or lens-shaped bodies with carbonates which vary in magnesium and calcium content. Irregular skarn horizons have been developed through metamorphism in contact zones between leptite and carbonate rock. These skarn zones are often associated with iron and sulfide mineralizaton (Magnusson, 1973). The underlying basement rock is not exposed, but old detrital zircons (2.7-1.95 Ga) in thick quartzites occur locally (Lundqvist, 1987). These quartzites suggest that 5 an older basement of granite lies below, exposed to erosion near the Bergslagen region. Various trace element and isotopic studies of leptites in the western Bergslagen reveal an even older basement felsic rock, of late Proterozoic and possibly Archean age (Vivallo & Richard, 1984). Most of the Bergslagen region comprises lower to upper amphibolite facies rock, with a higher grade in the north (Figure 4). There is one small region to the west which was only exposed to greenschist metamorphism, in which Gåsgruvan is located (Allen et al, 1996). Figure 4. Map of Bergslagen with related metamorphic facies, faults and shear zones. Location of Gåsgruvan is within the black circle (Stephens et al. 2009). The metavolcanic formations were originally thought to be undeformed and horizontal, but they have in fact endured a strong deformation and folding during the Svekokarelian orogeny (Magnusson, 1973). The supracrustal rocks were later intruded by some generations of calc-alkaline magmas. The first generation intruded the rocks of central Sweden during the Svekokarelian orogeny between 1.89-1.85 Ga. Other granite intruded the complex suite between 1.8-1.6 Ga (Oen et al. 1982). Mafic magma dikes also intruded the rocks during this time, which later were metamorphosed to metabasite. 6 Table 1. Table of stratigraphy for the Filipstad-Grythyttan-Hjulsjö region (Oen et al. 1982). Observations of stratigraphic and lithological data resulted in the development of a model for western Bergslagen. It concludes that in the early Proterozoic, a continental rift formed a large basin in which felsic volcanoclastic material was deposited (Oen et al, 1982). Tectonics of Bergslagen There have been many theories about the formation of the metavolcanic rocks and associated skarn and mineral assemblages in Bergslagen. Even today, its genesis and processes are not fully understood. Hietanen submitted a theory in 1975, suggesting that the metavolcanic rock series formed in a volcanic island arc system above a subduction zone (Hietanen, 1975). Some years later Böstrom et al, (1979) stated that the deposition at Långban may have formed at a spreading center below sea level, possible in a small basin. Oen et al, (1982) suggested another more promising model (Appendix 1), where Gåsgruvan is located just south of the Horrsjö block and to the west of Saxån basin. They reflect that the supracrustal series correspond to a Middle Proterozoic aulacogen rift system, where deposition suites and processes can be seen in table 1. 7 Allen et al, (1996) support Oen et al, (1982) and state that his model of continental rift volcanism in western Bergslagen appears to be right. They, however, suggest that the whole region was probably placed in an active continental margin and may be categorized as a continental back-arc region (Allen et al, 1996). Local geology & Site description Gåsgruvan belongs to the Bergslagen ore district, which stretches through the provinces Värmland, Närke, Västermanland, Dalarna, Uppland, and Gästrikland. The marble mine which is a part of the Gåsgruvefältet is located approximately 500 meters west of Lake Lyngen, approximately 5 km northeast of Filipstad, central west Sweden (Figure 5). Figure 5. Map of western Bergslagen with the location of Gåsgruvan and extension of Bergslagen region (shaded dark green in the inserted image of Sweden),(maps.google.se) (Ekomuseum Bergslagen, 2015) (inserted image). Gåsgruvefältet refers to all the mines within the Gåsgruvan marble and its surrounding skarn mineralizations, as well as Hållplatsgruvan and Liselundsgruvan (Figure 6). Gåsgruvan consists of an approximately 1400m long and 200m thick metamorphosed limestone lens. The marble formation dips relatively steeply, roughly 70° towards the southwest. The marble is embedded in fine-grained felsic 8 metavolcanic rock, called leptite. This rock is bordered in the west by a younger Svecokarelian granite suite, granite of Filipstad. The leptite is also bordered in the northeast by an older granite (> 1.85 Ga old), the Horrsjö Granite. This red to brown fine- medium-grained rock appears in a huge area in the Bergslagen of Filipstad (Åberg et al. 1983). An uneven pyroxene-garnet contact skarn has been formed between the marble and leptite, which can be seen as (skarn och järnmalm) in figure 6. This zone grows thinner into the marble, where it appears as lenses, veins, and spots. Figure 6. Map of Gåsgruvan and mines of Gåsgruvefältet (Magnusson, 1925). The marble, skarn, and surrounding leptite are intruded by three metamorphosed and deformed mafic intrusions with varying width, which strike to north-south to northwest-southeast. In addition, a diabase is intruding the field. Several mineral deposits have been explored within the skarn areas, mainly for iron but also for zinc and lead (Magnusson, 1925). There is a fissure or shear zone (Figure 13) with varying 9 width west of the mine, on the contact between leptite and marble, interbedded with skarn (SMA Mineral). This fissure zone may have acted as a transport passage for hydrothermal fluids from below, contributing to alteration of the rocks. Mineralization Gåsgruvan marble Gåsgruvan marble contains low magnesium, which is very unusual. In the central part, north of Igeltjärn (Figure 6), excluding some silica-rich inclusions, the marble contains 96-98% pure CaCO3 (Analysis 6, Table 2). Table 2. Analyzes of different carbonate rock at western Bergslagen. 1: Analysis of dolomite, Långban. 2: Average result of 6 analyzed dolomite from Långban. 3: Dolomitic limestone from Limbergsåsen, 4: poorly dolomitic limestone, Gåsborns limestone. 5: Dolomitic limestone, Persbergs odalfield. 6: Analyzed marble from Gåsgruvan. 7: Analysis of limestone, Limkullen (Magnusson, 1925). Despite the lack of magnesium, dolomite still exists, often as small inclusions or as decimeter-size enclaves in calcitic marble. As mentioned earlier, the marble contains disseminations of brucite. The brucite tends to be evenly distributed through the calcite-brucite segments as round 1-2 mm brown-black grains. Figure 7 may illustrate the appearance of the marble with disseminations of brucite. Dolomitization, hydration, and metasomatism gave rise to dolomite fragments and magnesium-rich mineralization in zones of higher magnesium (Allen et al, 1996). The mineralization of brucite may be related to this alteration, this matter will be further discussed later in the report. 10 Figure 7. Relatively clean calcite marble with an interval of black brucite dots. The picture is taken from an old drill core within the marble (SMA Mineral). Skarn The following mines have been mined within skarn areas of Gåsgruvan and can be seen in figure 6. Observations were made by investigating waste rocks piles of each mine. Järnvägsgruvan in the north is rich in marble with more or less regular bands of magnetite, serpentine, and pyroxene. The skarn is made of pyroxene, garnet, and amphiboles. The old concept Gåsgruvorna consisted of several mines in the eastern parts of the marble. The most northern mine was Mellangruvan and Bankobergsgruvan in the south with several mines between. The waste rocks of these show an enrichment of marble carrying magnetite, pyroxene, and a yellowish serpentine. Yellow serpentine is remarkably common in fissures in the marble. Brucite rich marble is also encountered. The waste rocks of Liselundsgruvorna in the west contain marble with magnetite, pyroxene and idiomorphic garnet. Blankagruvan to the north is very much the same as Gåsgruvorna, but pyrite was also located in fissures in the skarn. Metabasite has also been found in the waste rocks. Ladugruvan more to the south shows an enrichment of marble with brucite, in addition, a serpentine-diopside bearing skarn was observed. The brucite tends here to fill fissures in magnetite. Observations at Kobergs iron ore mine showed that the skarn consisted mostly of pyroxene and garnet, but also a dark serpentine, mica, and tremolite skarn. Kobergs zinc mine is located further to the south, which mainly contains sphalerite with some minor galena, chalcopyrite, and arsenopyrite. This mineralization sits as thin stripes in marble. The skarn consists of diopside, spinel, and mica. The garnet and pyroxene skarn of Hållplatsgruvan in the north is very rich in fissures and is intruded by granite with pegmatite and aplite, which often merge into quartz veins. Figure 8 may illustrate how magnesium skarn-altered marbe in Gåsgruvan could appear. 11 Figure 8. Highly magnesium skarn-altered marble with distinct black brucite dots and dark magnetite bands. Two dolomite cores are present in the upper left and middle of the picture, with haloes of green epidote, chlorite and yellowish serpentine (antigorite). The picture is taken from an old drill core within the marble (SMA Mineral). Three skarn horizons west of Lake Lyngen can be observed in figure 9 where the one closest to the beach is the highest stratigraphic unit. The one connecting with the marble of Gåsgruvan further to the left is the stratigraphically lowest unit, which means it is located in an anticlinal suite (Magnusson, 1925). 12 Figure 9. Map showing skarn and limestone horizons within Persbergs ore district, scale 1:40000 (Magnusson, 1925). Fissure zone The fissure zone (Figure 13) west of the marble neighboring the leptite is interbedded with skarn. The marble close to this zone tends to be rather altered and clayish and is often rich in green and yellow hydrous minerals as epidote, chlorite, and serpentine. The absence of brucite is due to high silica levels. The crushed marble weathers into a red to brown, even more breakdown and clayish mass (Figure 10), which is rich in hydrous limonite, epidote, chlorite and contain traces of sulfides. The clayish mass results in lots of drill core losses, as the material is highly porous (SMA Mineral). 13 Figure 10. Greenish marble in contact with a more red to brown hydrous altered mineralized rock in the fissure zone. The picture is taken from an old drill core near the marble-fissure zone boundary (SMA Mineral). Leptite The leptite surrounding Gåsgruvan has undergone metasomatic alteration in connection with skarn formation. The sodium-altered lower leptite (Figure 11) contains albitised plagioclase, chlorite, quartz, cordierite, gedrite and rare cummingtonite (Magnusson 1925). Figure 11. Felsic sodium altered leptite with chlorite. Picture is taken from an old drill core within the leptite, west of the marble (SMA Mineral). Metabasite The three mafic dark-green intrusions within the marble consist of mainly plagioclase interbedded in a matrix of hornblende (Figure 12). The plagioclase consists of Ab50An50 and is possessed with muscovite and epidote. The rock is at some places associated with magnetite, apatite and grains of pyrite (Magnusson 1925). 14 Figure 12. Mafic intrusion in the marble with younger felsic veins (SMA Mineral). Method Sampling Six marble samples were collected from the bottom of the open pit mine, at a level of ~50 meters depth. Five of these (GG10-GG15) were taken in a close to southeast pointing profile with an interval of ~40 meters, approaching an intruding metabasite body at a low angle (Figure 13). 15 Figure 13. Map showing sample localities, old boreholes, fissure zone and the metabasite in Gåsgruvan, made in ArcGIS 10.1. (The metabasite body wall, south of sample GG14 was roughly 2 meters away from sample GG15 when the samples were taken in May 2014). 16 Sample preparation The six marble samples (GG10-GG15) were first cut in half with a rock saw and one half was used for whole rock analysis. The remaining half was prepared for SEM analysis. All the sample preparation was done by the author at the University of Gothenburg, except the geochemical whole rock analysis of the pulverized marble samples, which were sent to ALS geochemistry service. Whole rock analysis preparation The six samples were first crushed in a cast iron pounder to fine gravel. Each gravel sample was then milled for 3 to 4 minutes in a vibratory disc mill in order to produce a homogenized sample with correct grain size, which is necessary for a precise ICPMS geochemistry analysis. SEM rock slabs preparation Each rock slab was sawn against the foliation, to 3-5mm thick, 4cm long and 2cm wide. It was then polished on a glass plate with 200 mesh (74µm) aluminum powder for 5 minutes, then 400 mesh (37µm) for another 4 minutes. The slabs were then mounted under a weight and polished for 1h in a vibrating polishing machine, using aluminum powder grit of 600 mesh (10µm). Before they could be analyzed with the scanning electron microscope, they had to be carbon coated. This is done in order to prevent charge build-up within the sample during analysis. Analytical methods Whole rock chemistry analysis (ALS) The pulverized samples sent to ALS geochemistry service were analyzed with inductively coupled plasma mass spectroscopy and atomic emission spectroscopy (ICP-MS & ICP-AES). A complete package of 5 different analytical methods yielding 65 elements in total (appendix 2) was ordered with a sample cost of 95 US dollar per sample. The chemical data analysis done by ALS can be seen in appendix 3. ME-ICP06 Analysis A lithium metaborate & lithium tetraborate flux of 0.9 g was mixed well with the prepared sample of 0.2 g, before fusion in a furnace at 1000°C. 100 mL of 4% nitric acid and 2% hydrochloric acid was then used to dissolve the melt after cooling. The solution was then analyzed with ICP-AES. ME-MS81 & ME-4ACD81 Analysis 0.2 g of each sample was added to a lithium metaborate flux of 0.9 g, mixed and fused in a furnace at 1000°C. After the melt had cooled, it was dissolved in 100 mL of 4% HNO3 and & 2% HCl3 solution. The solution was then ready for ICP-MS analysis. It is not ideal to analyze base metal content with this method, but this can be done by digesting the samples with four acids (ME-4ACD81) (alsglobal.com). Scanning Electron Microscopy All six rock slabs were analyzed with the scanning electron microscope (SEM) at the University of Gothenburg, using a Hitachi S-3400N machine. It operates at high vacuum and a specimen current of 6.0nA at 20kV and a working distance of 9.6 mm. The instrument is calibrated with an Oxford instrument energy-dispersive X-ray analytical system. All samples were analyzed using the backscatter electron detector. 17 XRF (Old boreholes, SMA) Representative old XRF-analysis data from mapped boreholes in the mine is used to produce various major element diagrams, in order to appreciate chemical patterns and characteristics of the marble. These interpretations are then compared and related with the recently analyzed ALS- and SEM-data. Results & Interpretation Scanning Electron Microscope (SEM) Sample GG10 SEM backscattered electron image (BSE) interpretation Site 1 in figure 14 consists of mostly a matrix of calcite and small grains of dolomite, derived by dolomitization of calcite in contact with magnesium-rich sea water. The small dolomite crystals are scattered throughout the calcite matrix meaning the recrystallization took place at an early stage. The sample contains retrograde antigorite with cores of forsterite. This means the rock has been experienced a high temperature to form forsterite, followed by cooling and hydration to form antigorite through serpentinization (Kelemen, 2012). Magnetite crystals are present where some may originate from serpentinizaton of olivine. Site 2 (Figure 15) displays retrograde serpentinization as a pseudomorph mesh texture of a big single olivine crystal in a matrix of calcite with associated dolomite. This alteration also contains some minor magnetite. Site 3 (Figure 16) is more zoomed out and display several forsterite crystals being altered to antigorite in a matrix of calcite. It also contains forsterite with a rim of spinel. This spinel reaction rim indicates that its forsterite core wasn´t in equilibrium with the surroundings (enriched in Al and depleted in SiO2), meaning that the serpentinization could not continue. Figure 17 shows site 4 which contains retrograde clinochlore in calcite where some chlorite is situated as a rim of spinel. This chlorite aureole may have been altered by spinel releasing Mg and Al during retrograde metamorphism in the presence of MgO- and SiO2-rich fluids (Kimball, 1990). 18 Figure 14. Site 1 of sample GG10 illustrates antigorite (serpentine) rims surrounding forsterite cores in a matrix of calcite associated with minor dolomite. The bright mineral in the middle is magnetite in contact with antigorite. Figure 15. Site 2 of sample GG10, displays pseudomorph retrograde antigorite formed by serpentinization of forsterite. Magnetite crystals are also present. 19 Figure 16. Site 3 from sample GG10 shows cores of forsterite with corona rims of antigorite in calcite, with a spinel rim in contact with antigorite. Figure 17. Site 4 from sample GG10 with both apatite and spinel crystals within clinochlore. 20 Sample GG11 SEM backscattered electron image (BSE) interpretation GG11 (Figure 18-23) has undergone a stronger dolomitization with further recrystallization, although the rock is still dominated by calcite. The sample is also very low in silica. Figure 18 shows site 1 where brucite was found in contact with large dolomite (pseudomorphs) and as rims in magnetite grains. Just a little forsterite and antigorite were present here. Site 2 (Figure 19) displays dolomite in calcite containing brucite with a core of periclase. The brucite has small inclusions of magnetite, which may be due to olivine breakdown with small parts of iron (fayalite) content. The rock may have been affected by a higher temperature, judging from the periclase grain in the brucite (Bucher, 1981). A strong serpentinization of forsterite is located in site 3 (figure 20) which is a sign of hydration with decreasing temperature. Brucite is even here located as rims around magnetite, inside antigorite and in calcite. Magnetite inclusions in brucite are not evident. Site 4 in figure 21 shows a big brucite grain with magnetite inclusions in contact with dolomite in a matrix of calcite. Some antigorite is also present in contact with dolomite. Site 5 (figure 22) is another image displaying brucite in the rim and cleavage of a magnetite grain in calcite. Brucite in the rims and cleavage of spinel is present in site 6 (figure 23). Brucite is also here located in contact with dolomite and calcite, but only one grain of brucite contains apparent inclusions of magnetite. Some antigorite is also present. Figure 18. Site 1, sample GG11 detector. Brucite in contact with dolomite and magnetite in calcite. Antigorite and forsterite sit together in the lower right corner. 21 Figure 19. A closed zoomed brucite crystal in dolomite at site 2 from sample GG11. The brucite got traces of small magnetite inclusions and it´s likely possessing a core of periclase. Figure 20. Sample GG11 at site 3, shows antigorite surrounding forsterite crystals adjacent to dolomite and magnetite. Brucite formations occur as in rims of magnetite and inside antigorite. 22 Figure 21. Large brucite crystal in dolomite (pseudomorph) from sample GG11 at site 4. The brucite holds small inclusions of magnetite. Antigorite next to dolomite. Figure 22. Brucite formations in the rim, core and cleavage of a magnetite crystal from sample GG11, site 5. 23 Figure 23. Site 6 from sample GG11, illustrating brucite next to dolomite, in the cleavage and rim of spinel. White minerals are magnetite. Sample GG12 SEM backscattered electron image (BSE) interpretation GG12 (Figure 24-26) illustrates skarn inclusions in the marble with a high and variable augite content. This sample does contain higher silica content, thus no periclase or brucite are located. All the Mg is situated in augite and dolomite doesn’t occur. Titanite can be observed through the sample. The skarn may have originated from hydrothermal fluids from fissures or from contact metamorphism by an intruding metabasite. Tremolite, forsterite and water most likely altered to augite and antigorite at lower temperatures and albite-rich plagioclase started to grow when fluids were enriched in sodium. 24 Figure 24. Site 1 from sample GG12 consists of augite (diopside-hedenbergite) and some albite in contact with augite in a matrix of calcite. All white smaller crystals are titanite. Figure 25. Site 2 from sample GG12, illustrating augite with connected albite in calcite. Associated titanite is present (white minerals). 25 Figure 26. Site 3 from sample GG12 consists of calcite in a matrix of augite with a more frequent titanite mineralization (bright minerals). Sample GG13 SEM backscattered electron image (BSE) interpretation Figure 27–29 illustrates a matrix of calcite, which has endured dolomitization and forsterite serpentinization. The high content of silica is probably the main factor why brucite formation is excluded here. Site 1 in figure 27 shows a matrix of calcite with dolomite and antigorite with minor of forsterite. Magnetite is also present as inclusions in antigorite, where iron sited in forsterite were released through serpentinization. Clinochlore is most certainly a product of retrograde alteration of forsterite related to mafic hydrothermal liquids. Site 2 (Figure 28) contains dolomite, forsterite, and clinochlore in a matrix of calcite. A sphalerite grain was found which may have been mobilized through hot fluids in fissures from nearby skarn ores. Figure 29 shows an image of site 3 where dolomite and clinochlore can be located in a calcite matrix, thus no forsterite or antigorite are present. Sphalerite and magnetite still occur. 26 Figure 27. Sample GG13, site 1 Contains dolomite and small forsterite inclusions in antigorite. Clinochlore mineralization in calcite also exists. Figure 28. Site 2 from sample GG13. The picture shows dolomite in calcite, and clinochlore adjacent to forsterite. The bright mineralization is sphalerite. 27 Figure 29. Dolomite and clinochlore in calcite from sample GG13, site 3. Sphalerite mineralization lay in contact with dolomite and magnetite in calcite. Sample GG14 SEM backscattered electron image (BSE) interpretation Signs of dolomitization of calcite in sites 1-2 (Figure 30-31) are present and the matrix consists of calcite. At some places, one can see more magnesium rich clusters of forsterite surrounded by antigorite which evidences retrograde serpentinization of forsterite. Even this sample lacks brucite due to high silica. An additional source of aluminum gave rise to spinel in site 2 (Figure 31) which with calcite and forsterite formed clinochlore together with dolomite at a lower temperature (Bucher, 1981). 28 Figure 30. Sample GG14, site 1 showing forsterite in antigorite (pseudomorph mesh texture) along with clinochlore. Bright minerals are magnetite and the gray small dots in calcite are dolomite. Figure 31. Site 2 from sample GG14 illustrates clinochlore surrounding forsterite crystals in its rims and cleavage. Dolomite and spinel are also current. 29 Sample GG15 SEM backscattered electron image (BSE) interpretation This rock sample (Figure 32-35) shows no signs of dolomitization and the matrix dominates of calcite. Very little forsterite is present (Figure 35, site 4), it has largely been replaced by antigorite, which means the rock has been strongly serpentinized at a relatively low temperature. This rock may have been affected by a more felsic intrusion as frequent inclusions of clinochlore occurs (Figure 33-35, site 2-4). Clinochlore is most likely a product of chloritization of forsterite at a decreasing temperature. This is probably the reason for Mn-ilmenite (pyrophanite) and magnetite (Figure 32-33, site 1-2) formation as forsterite releases iron with associated manganese and titanium during its breakdown (Fleet, 2006). Figure 32. Site 1 of sample GG15 displaying antigorite in calcite with prehnite, pyrophanite, and magnetite. The dark-grey dotted area around the calcite to the right consists of small inclusions of antigorite in calcite. 30 Figure 33. Sample GG15 site 2, elongated magnetite crystals in calcite and pyrophanite inclusions in clinochlore. Figure 34. Clinochlore and antigorite in calcite from sample GG15 at site 3. 31 Figure 35. Site 4 from sample GG15 showing forsterite and clinochlore in a matrix of calcite, with associated apatite in the top right. 32 Geochemical Analysis, ALS Variation Diagrams Figure 36. Variation diagrams showing the relation of major oxides, considerable sulfides, and the more mobile REE lanthanum plotted against SiO2 in Gåsgruvan. Diagram a-e are plotted from marble samples GG10-GG15 with data analyzed by ALS. In addition, diagram e) contains data from old boreholes analyzed with XRF by SMA Mineral. Looking at figure 36a, one can see that the Al2O3 content increases as SiO2 does, and they are well connected with each other. The occurrence of clinochlore and albite (GG12) are dependent on aluminum and silica content. The MnO content (Figure 36b) seems to clearly decrease with increasing silica, thus it should be associated with magnetite. The sulfides plotted in figure 36c show an obvious positive trend with the increase of silica. These sulfides may have been mobilized through post hydrothermal solutions derived from younger intrusives. Plotted lanthanum (Figure 36d) being the most mobile REE shows an increasing trend with a higher amount of silica. La is widely dispersed in trace quantities in minerals such as pyroxene, feldspar, biotite and apatite and may originate from the granite intrusives (Salimen, Plant, & Reeder, 33 2006). The diagram in figure 36e contains more than 1500 data points located all over the mine. It seems to illustrate two different trends for alteration. One is silica poor with significant increases in Mg that can be interpreted as dolomitization, and one is silica-rich interpreted as magnesium-skarn altered marble. Thus, this statement is rather uncertain where variable silica content could be either due to original quartz or clay minerals or to the hydrothermal addition of silica with associated Mg. Only one sample has brucite (Figure 18, GG11), namely the one with the lowest silica and highest magnesium content. The high amount of silica in sample GG12 is very apparent as augite in figure 26. Figure 37. Variation diagrams showing the relation of some major oxides with barium and strontium plotted against MgO in Gåsgruvan. Diagram a-d are plotted from marble samples GG10-GG15 with data analyzed by ALS. The relationship between CaO and MgO is relatively comprehensible where magnesium enrichment seems to lower the calcium content of the marble, except for sample GG13 (Figure 37a). This is thought to be highly related to early dolomitization and other magnesium alteration. The content of Fe2O3 (total) in all samples but GG12 (Figure 37b) seems related with the content of MgO, where higher magnesium increases the iron content. The iron seems primarily bounded in magnetite, often in connection with brucite (Figure 21). Some iron is also situated in olivine crystals as fayalite. Figure 37c & 37d appear to be rather similar except Sr content is higher. Their content decreases with an increasing magnesium value. Ba2+ and Sr2+ tend to replace Ca2+ in calcite, due to their smaller ionic potential. Ba2+ is by Goldschmidt´s rule less abundant in calcite than Sr2+ (Faure, 1998). They also substitute for Ca in plagioclase, hence the high content in GG12 (Figure 37c & 37d) (Winter, 2001). 34 Rare Earth Elements Figure 38. Chondrite-normalized (Evensen, 1978) REE and Y patterns calculated for samples GG10GG15. All the REE and Y data for the marble is averaged in the logarithmic scale. Sample G1B is taken from another location in Bergslagen from an altered dolomite in contact with a gabbro intrusion (Hogmalm et al. 2012). The REE and Y abundance patterns for Gåsgruvan marble (Figure 38) are rather similar with the exception of sample GG12. They show a relatively low content of rare earth elements in all the samples, hence REE appears not affected by hydrothermal alteration. The patterns also exhibit an enrichment of light REE, relative to heavy ones and contain negative Eu anomalies (Boulvais et al. 2000). The negative Eu anomaly could be connected with the substitution of Eu2+ for Ca in plagioclase. Thus the hydrothermal liquid was at one time in equilibrium with former plagioclase, possibly originated from intruded granites (Winter, 2001). The positive Tm anomalies should be an analytical error. The sample (GG11) containing brucite with the most magnesium and least silica holds the smallest REE content with the lowest Eu anomaly. The patterns look similar compared with a strongly altered dolomite sample (G1B) from a magnesite deposit (30km east of Gåsgruvan) affected by a gabbro intrusion (Hogmalm et al. 2012). The REE patterns don´t relate with seawater interaction. Therefor seawater interference generally affects the REE with a fingerprint of a progressive enrichment of heavy REE, relative to the light REE. They also exhibit a depletion of Ce and an enrichment of La (Piper & Bau, 2013). XRF mapping, SMA Mineral Following graphs represent one borehole each, illustrate measured major elements in weight percent (marble only). Attached drill-core mapping is located below each graph and location for each hole can be seen in figure 13. XRF-analysis and drill-core mapping were done by SMA Mineral. 35 Figure 39. XRF data with mapping, from borehole 535. It’s drilled towards the northeast with a 45° dip, which probably goes below the interpreted metabasite intrusion (Figure 13). (MgO, Fe2O3, Al2O3 and MnO are plotted against the secondary axis). Figure 40. XRF data with mapping from borehole 544. It´s drilled far out, southwest of the marble, dipping 45° towards the northeast with its approximately 300 meter length (Figure 13). (MgO, Fe2O3, Al2O3 and MnO are plotted against the secondary axis). 36 Figure 41. Diagram made from XRF data with mapping from borehole 621 (Figure 13). This borehole is drilled horizontally towards the southeast and it´s almost 100 meters long. (MgO, Fe2O3, Al2O3 and MnO are plotted against the secondary axis). Figure 42. XRF data with mapping from borehole 628 (Figure 13), which is dipping 45° towards southeast. This borehole is approximately 225 meters long. (MgO, Fe 2O3, Al2O3 and MnO are plotted against the secondary axis). 37 What first can be noted by observing the diagrams (Figure 39-42) is the pattern of MgO and CaO, which tend to be the complete opposite of each other. This may be controlled entirely by calcite dolomitization. Dolomite often occurs together with olivine and serpentine, which at some places is due to positive SiO2 and MgO anomalies, even though silica and Mg don’t appear that correlated. Another obvious observation is that Al2O3 is highly related to SiO2. This either reflects alteration by silica- and Al-rich fluid, or more likely the original content of clay minerals in the limestone. Positive Fe2O3 (total) anomalies tend to follow MgO as olivine breakdown releases iron which oxidizes to iron oxides. Different amount of silica in the mapped marble and marble with brucite areas reflect magnesium silicate zones within the marble, such as olivine, serpentine, and chlorite. An important observation is that brucite mineralization is found mainly in high magnesium rocks and seems highly related with dolomitization. Discussion Brucite Brucite was only situated in one of the taken samples (GG11), which reflected the most Mg-rich and probably strongest dolomitized sample. GG13 & GG14 containing almost as much magnesium as GG11 could have the potential of exhibit brucite, although the higher content of silica (Figure 36e) probably compromised the magnesium through skarn alteration. Here brucite was in contact with mainly large dolomite crystals, but also forsterite and serpentine. Some brucite was even situated in rims and cleavage of magnetite and spinel mineralization. Most of the brucite in contact with dolomite show signs of small magnetite inclusions. These crystals may be related with retrograde olivine serpentinization, where forsterite hydrates to serpentine and brucite when it comes in contact with water- and silica-rich hydrothermal fluids around 370-400°C (Figure 44, reaction 4). During olivine breakdown, it releases iron from its endmember fayalite, which oxidizes to magnetite (Winter 2001). Only one single brucite crystal was seen to have a core of periclase (Figure 19). Such brucite with a core of periclase in limestone is exactly what A.E Törnebohm found in Värmland in 1878. Hydration of periclase to brucite (Figure 43, reaction 5 & Figure 44, reaction 2) is thought to take place below about 600°C at 1kbar in conditions of low silica and XCO2 ≤ 0.05 (Gerdes et al. 1999). This temperature correlates with amphibolite facies, which is too high for the regional metamorphic grade of greenschist facies (Figure 4). This is strong evidence that some areas within the marble have endured local contact metamorphism of amphibolite grade due to the mafic intrusions within the marble. Space in the cleavage of spinel and magnetite has been filled with brucite (Figure 22 & 23) crystallized from late postmagmatic fluids rich in water and magnesium. This can occur in a relatively low-temperature environment (200°C), where brucite tends to act as a fracture filling mineral (Magnusson, 1925). They may also have formed directly from dedolomitization (Figure 43, reaction 9) at very low CO2 partial pressure and high H2O partial pressure between 470-600°C (Gerdes et al. 1999). This process may be hard to prove by looking at the SEM pictures, but these brucite crystals are probably not derived from forsterite serpentinization, because they don’t contain any magnetite inclusions. If however iron was released, it may have been absorbed by existing magnetite crystals around the brucite. 38 In aluminous dolomite poor in silica, they often contain various amounts of Mgchlorite (clinochlore), which is stable in greenschist and amphibolite facies. This clinochlore reacts with dolomite at 4 kb around 610°C and 680°C to form forsterite + spinel + calcite + H2O + CO2 (Figure 44, reaction 5). Figure 43. T-XCO2 phase diagram for a siliceous dolomite in a CaO–MgO–SiO2–H2O–CO2 system, calculated using the Holland & Powell (1990) thermodynamic database (Gerdes et al. 1999). The occurrence of spinel is also evidence for higher temperatures in amphibolite facies. The newly formed forsterite may have cooled down to around 400°C, where in contact with water it hydrates to form antigorite, and later brucite when remaining liquid is poor in silica and CO2. The early periclase however shows that some brucite has its origin in the high-grade event, formed by retrogression as the temperature fell. The marble sample GG11 is the only sample in which clinochlore is absent. This could mean that the stability field of the assemblage chlorite + dolomite has been exceeded, either because of a too high temperature or because of an external compositional control of the thermal liquids by surrounding granite. The marble samples (GG13 & GG15) are by contrast lacking spinel, meaning the stability field of clinochlore + dolomite has not yet been exceeded (Bucher, 1981). Metamorphism There is no secret that a combination of forces during the Svecokarelian orogeny have influenced the area and made it rather complex and tricky to interpret. Two generations of granitic magmas intruded the region during this orogeny contributing with hydrothermal liquids and deformation. At the same time, mafic sills and dikes intruded the region and three known intrusions penetrated the marble of Gåsgruvan. These mafic sills and dikes intruded the rocks, which gave rise to high-temperature skarn alterations through metasomatic processes. The pressure while these intrusions took place is thought to have been relatively low, around 1kbar. The whole system resembles a retrograde metamorphic event affecting a higher grade rock, (i.e. higher 39 “grade” minerals to lower ones, due to a decrease in temperature). Serpentine pseudomorphs of forsterite (Figure 30) and lower grade chlorite rims around spinel and forsterite (Figure 17 & 31) are great evidence of retrograde metamorphism. Prograde spinel and periclase formed at the highest temperature, over 600°C (at given pressure). Granitic magmas do not commonly generate such high temperatures, but they could be achieved by mafic intrusions. Sample GG12 (Figure 24-26) contains a lot of diopside, which could be explained by the retrograde reaction (6) tremolite + forsterite + H2O = diopside + antigorite when the temperature has cool down to around 525°C (Figure 44, reaction 6). This is the highest temperature where antigorite is stable and first introduced in the system. When the altered skarn has cooled down even more (370-400°C), forsterite begins to hydrate to antigorite and brucite. They become unstable below 260°C and create chrysotile (Figure 44, reaction 7), which is a serpentine less rich in magnesium than antigorite (Winter 2001). Figure 44. Summary of hydrothermal brucite alterations in the marble of Gåsgruvan. Pressure is set to 1kb. Hydrothermal Fluids Magnusson (1925) pointed out that genesis of brucite is related with hydrothermal fluids from younger erupted granitic magmas, such as granite of Horrsjö in the north and granite of Filipstad in the west. He also stated that brucite mineralization is related with contact metamorphism of dolomite (Magnusson, 1925). His statements seem correct where intruding granites appear to have enriched the marble in magnesium through metasomatic processes, leading to dolomitization. Further magnesium development and high-temperature hydrothermal fluids emerged once the mafic sills and dikes intruded the dolomitized marble. Fissures in the marble 40 acted as fluid passages leading to stronger hydrothermal alteration in greater extension. The hydrothermal fluids generated by the mafic rocks must as well have been enriched in silica, aluminum and iron looking at the mineralization of the marble samples. These elements and others got leached out from wall rocks of the intrusions continuing path through the crust, felsic basement granites, leptites and finally the overlying gray and black slate formations. The eroded overlying slate formations containing clay minerals may have been the substantial source of aluminum and silica as the intrusions hydrothermal solutions leached them out. The taken samples show a relatively low content of REE elements for being exposed by pretty strong hydrothermal alterations. It´s rather uncertain the Eu anomalies (Figure 38) are derived by hydrothermal fluids from plagioclase-bearing intrusives or basically inherited from the marble protolith, or a combination of both (Whitney & Olmsted, 1998). Hogmalm et al. (2012) investigated magnesite replacement formation in a calcitic or dolomitic precursor rock, which was intruded by a gabbro intrusion in Bergslagen. This gabbro gave rise to medium temperature hydrothermal fluids associated with seawater, which probably gave rise to magnesite alteration. The REE plot of their dolomite (G1B, Figure 38) is relatively similar to the marble samples at Gåsgruvan, except their dolomite has higher REE (Hogmalm et al. 2012). It is hard to point out the reason for this. The small enrichment of light REE (LREE) in sample G1B may be due to that REE rather substitutes in calcium than in magnesium. Hence, the calciterich marble of Gåsgruvan has higher (LREE) enrichment. The liquid for diagenetic dolomitization in the samples may originate from seawater interaction, however, the low amounts of Sr (<73 ppm, Figure 37d) may indicate otherwise as it should be of hydrothermal origin. Dolomitization associated with seawater interaction should possess Sr-values of several hundred ppm (Gasparrini, Thilo, & Boni, 2006). The REE pattern (enriched in LREE, relative HREE) is also not in favor for seawater interaction. Every mentioned alteration seems very magnesium and dolomite dependent, where everything is being controlled by the content of magnesium and silica, as well as the pressure of water and carbon dioxide. The marble contains areas with pure calcite with no magnesium alteration whatsoever. Then there are disseminations of dolomite with calcite and skarn alteration. If conditions of low silica & CO2-pressure and high H2O-pressure & alkalinity are present, brucite may form by hydration of magnesium minerals. This has also been recognized in the past by Oen et al. in 1982 where they saw alterations of tremolite and chlorite-serpentine skarn in contacts between limestone and metabasite, which they called “sköl-areas”. They often found sköl areas with sulfide impregnations along shear and fracture zones. Outside “Sköl-areas” marble and metabasite instead show a sharp contact without any magnesium skarn alterations (Oen et al. 1982). The measured loss on ignition (LOI, Appendix 3) reflects the content of volatiles (CO2+H2O) present in the marble samples. The average LOI values of all the samples are 42.1%, excluding sample GG12 (Figure 26), which acquired 36% due to the high silica content. This indicates high volatile content and the significance of high carbonate content since it is equal with the development of carbon dioxide after heating over 900 °C in a furnace (Onimisi, 2013). 41 Future studies The samples may not have been placed at the perfect locations for the purpose of studying the brucite alteration affected by the high-temperature mafic intrusion. The mafic sills and dikes are most certainly somewhere below the surface of the sample areas, making it hard to interpret their influence. What can be done for future work is to take carbonate samples containing brucite, more proximal to a single known metabasite intrusion, without risking interference with other sills and dikes. The interval between samples shouldn’t be greater than one meter. Multiple samples should also contain brucite, not just one. Performing a calcite-dolomite geothermometer could help determine the temperature of calcite dolomitization, which is helpful with the interpretation alteration processes. Possessing 18O/16O and 87 Sr/86Sr isotope ratios would be a useful compliment in the attempt to interpret the fluid source of alteration. Geologists of the mine could use a handheld XRF to analyze the rock walls in order to detect any unwanted mineral and alteration zone. 42 Conclusions Brucite mineralization is related with hydrothermally Mg-metasomatic processes in contact metamorphism of dolomite and hydration of various Mgbearing minerals. Brucite tends to be stable at a differential range of temperatures between 600 and 260°C at 1 kbar, with high Mg- and low SiO2-content related with H2Orich fluids. Mineralization of spinel and periclase are good evidence that local mafic intrusions in the marble raised the metamorphic grade from greenschist facies into amphibolite facies, and gave rise to low XCO2 fluids. These mafic sills and dikes could also have generated brucite by hydration of high-temperature periclase. The system then underwent retrograde reactions of higher grade rock with a decrease in temperature, where serpentine pseudomorphs of forsterite and chlorite corona texture around spinel and forsterite are a great indication of this. The calcite dolomitization got its magnesium from granitic and mafic intrusive wall rocks through metasomatic leaching as they ascended through the crust, near to metavolcanic and overburden sedimentary rocks. 43 Acknowledgement I would like to thank my supervisor at SMA Mineral, Magnus Johansson for providing me with this opportunity and letting me take samples and work with their drill cores, and providing me with the desired counseling. I also want to thank my supervisor, Johan Hogmalm, and examiner, David Cornell at the University of Gothenburg for their dedication and time spent on this project, and for contributing in dedicated discussions and criticisms. 44 Bibliography Allen, L. (1996). Facies Analysis of a 1.9 Ga, Continental Margin, Back-Arc, Felsic Caldera Province with Diverse Zn-Pb-Ag- (Cu-Au) Sulfide and Fe Oxide Deposits, Bergslagen Region, Sweden. Economic Geology, v. 91, 979-1008. Boulvais, P., Fourcade, S., Moine, B., Gruau, G., & Cuney, M. (2000). Rare-earth elements distribution in granulite-facies marbles: a witness of fluid–rock interaction . Elsevier, 117-126. Bucher, K. (1981). Petrology of chlorite-spinel marbles from NW Spitsbergen (Svalbard). LITHOS, 203-213. Bucher, K., Frey, M. (2002). Petrogenesis of Metamorphic Rocks. Berlin: Springer-Verlag Berlin Heidelberg. Böstrom, K., Rydell, H., and Joensuu, O. (1979). Långban - an exhalative sedimentary deposit? Econ. Geol, 1002-1011. Ekomuseum Bergslagen. (2015, March 26). Retrieved from Stiftelsen Ekomuseum Bergslagen: http://ekomuseum.se/?page_id=1336 Evensen N,M,, Hamilton P,J,, and O'Nions R,K. (1978). Rare-earth abundances in chondritic meteorites. Geochimica et Cosmochimica. v42, 1199-1212. Faure, G. (1998). Principles and applications of geochemistry. New Jersey: Prentice Hall. Filipstads Bergslag. (2011, 02 22). Bergshanteringen i Filipstads Bergslag. Retrieved from Filipstads Bergslag: http://www.filipstadsbergslag.com/gruvor/persberg/gasgruvan.html Fleet, M. E. (2006). Rock forming minerals: Micas. London: The Geological Society. Gasparrini, M., Thilo, B., & Boni, M. (2006). Massive hydrothermal dolomites in the southwestern Cantabrian Zone (Spain) and their relation to the Late Variscan evolution. Marine and Petroleum Geology, 1-26. Gerdes, M, Baumgartner, L, Valley, J. (1999). Stable Isotopic Evidence for Limited Fluid Flow through Dolomitic Marble in the Adamello Contact Aureole, Cima Uzza, Italy. Journal of petrology (40), 853-872. Griffin, W, Helvaci, C. (1983). Metamorphic feldspathization of metavolcanics and granitoids, Avnik area, Turkey. Mineral. Petrol, 309-319. Hellingwerf, R. H. (1984). Paragenetic Zoning and Genesis of Cu-Zn-Fe-Pb-As Sulfide Skarn Ores in a Proterozoic Rift Basin, Gruvfsen, Western Bergslagen, Sweden. Economic Geology, 696-715. Hietanen, A. (1975). Generation of potassium-poor magmas in the northern Sierra Nevada and the Svecofennian of Finland. U. S. Geol. Surv, 681--645. Holland, T. J. B. & Powell, R. (1990). An enlarged and updated internally consistent thermodynamic database with uncertainties and correlations: the system K2O–Na2O– CaO–MgO–MnO–FeO–Fe2O3–Al2O3–TiO2–SiO2–C–H2–O2. Journal of Metamorphic Geology 8, 89-124. Igelström, L. J. (1858). Om ett för Sverige nytt mineral. Övers. af Kongl. Vek. Ak. Förh. Ionescu, C. (1998). The Genesis of Brucite - Mg(OH)2. A general review. Geologia, XLIII, 1, 97-102. K. Johan Hogmalm , Rob Hellingwerf , David H. Cornell & Friedrich Finger. (2012). An epigenetic magnesite deposit in Bergslagen area, central Sweden. GFF, 134:1, 7-18. Kelemen, P. B. (2012). Reaction-driven cracking during retrograde metamorphism: Olivine hydration and carbonataion. Earth and planetary science letters, 81-89. Kimball, K. L. (1990). Effects of hydrothermal alteration on the compositions of chromian spinel. Contributions to Mineralogy and Petrology, vol.105, 337-346. Lindström, M, Lundqvist, J, Lundqvist, T. (2000). Sveriges geologi från urtid till nutid. Lund: Studentlitteratur. Lundqvist, T. (1987). Early Svecofennian stratigraphy of southern and central Norrland, Sweden, and the possible existence of an Archean basement west of the Svecokarelides. Precambrian Research, v. 35, 343-352. Löfgren, C. (1979). Do leptites represent Precambrian island arc rocks? Lithos, 159-165. 45 Magnusson, N. H. (1925). Persbergs malmtrakt och berggrunden i de centrala delarna av Filipstads Bergslag. Stockholm: Victor Pettersons Bokindustriaktiebolag. Magnusson, N. H. (1973). Malm i Sverige 1, Mellersta och södra Sverige. Almqvist & Wiksell AB. Oen, I.S., Helmers, H., Verschure, R.H. & Wiklander, U. (1982). Ore deposition in a Proterozoic incipient rift zone environment: A tentative model for the FilipstadGrythyttan-Hjulsjö region, Bergslagen, Sweden. Geol Rundschau, 182-194. Onimisi, M., Obaje, N., & Daniel, A. (2013). Geochemical and petrogenetic characteristics of the marble deposit in Itobe area, Kogi state, Central Nigeria. Advances in Applied Science Research ,4(5), 44-57. Piper, D. Z., & Bau, M. (2013). Normalized Rare Earth Elements in Water, Sediments, and Wine: Identifying Sources and Environmental Redox Conditions. American Journal of Analytical Chemistry, 69-83. Rogers, A. (1918). American occurance of periclase. American Journal of Science. Salimen, R., Plant, J., & Reeder, S. (2006). Geochemical atlas of Europe. Part 1, Background information, methodology and maps. Geological Survey of Finland. Stephens, M.B., Ripa, M, Lundström, I., Persson, L., Bergman, T., Ahl, M., Wahlgren, C-H., Persson P-O., and Wickström, L. (2009). Synthesis of the bedrock geology in the Bergslagen region, fennoscandian shield, south-central Sweden. Sveriges geologiska undersökning, 259. Turner, F. J. (1965). Note on the genesis of brucite in contact metamorphism of Dolomite. Beiträge zur Mineralogie und Petrograpliie 11, 393-397. Wellin, E. Wikander, U. & Kähr, A.M. (1980). Aradiometric study of a quartz-porphyritic Krhyolite at Hällefors, Örebro, county, Sweden. Lithos, 147-152. Whitney, P., & Olmsted, J. (1998). Rare earth element metasomatism in hydrothermal systems: The Willsboro-Lewis wollastonite ores, New York, USA . Geochimica et Cosmochimica Acta (62), 2965-2977. Winter, O. D. (2001). An Introduction to Igneous and Metamorphic Petrology. New Jersey: Prentice-Hall Inc. Vivallo, W & Richard, D. (1984). Early Proterozoic ensialic spreading subsidence: Evidence from Carpenberg, central Sweden. Precambrian Research. v. 26, 203-221. Åberg, G., Bollmark, B., Björk, L., & Wiklander, U. (1983). Radiometric dating of the Horrsjö granite, south central Sweden. GFF, vol (105), 78-81. 46 Appendix 1: Middle Proterozoic rift system 47 Appendix 2: ALS geochemistry whole rock analysis package 48 Appendix 3: ALS geochemistry whole rock analysis data Oxide (%) Element (ppm) SiO2 Al2O3 Fe2O3 CaO MgO Na2O K2O Cr2O3 TiO2 MnO P2O5 SrO BaO LOI Total Ba Co Cr Cu Zn Hf Sc V Y Zr Nb Ni Pb Rb Th U Sn Sr Ta Tb Cs Dy Er Ga Gd Tm W As Bi Hg Sb Se Te Sample GG10 1,45 0,2 0,38 50,8 3,11 <0.01 0,01 <0.01 0,02 0,17 <0.01 <0.01 <0.01 42 98,14 GG11 0,73 0,2 0,45 47,9 5,33 0,03 0,01 <0.01 0,01 0,12 <0.01 <0.01 <0.01 43,3 98,08 GG12 10,15 1,45 0,86 50,1 2,49 0,08 0,06 <0.01 0,04 0,05 <0.01 <0.01 0,01 36 101,29 GG13 2,17 0,44 0,67 51,3 5,41 <0.01 0,02 <0.01 0,02 0,1 <0.01 <0.01 <0.01 41,4 101,53 GG14 2,53 0,69 0,56 49,2 4,43 <0.01 0,02 <0.01 0,02 0,05 <0.01 <0.01 <0.01 41,4 98,9 GG15 1,84 0,4 0,43 50,4 3,41 <0.01 0,02 <0.01 0,02 0,12 <0.01 <0.01 <0.01 42,5 99,14 5,8 2 10 28 20 0,3 <1 <5 1 11 <0.2 <1 2 0,9 1,16 1,16 1 52,3 <0.1 0,03 0,03 0,17 0,1 0,4 0,24 0,03 1 0,2 0,02 <0.005 <0.05 0,6 0,02 3,4 2 <10 1 9 0,2 <1 <5 0,8 5 <0.2 <1 <2 0,7 0,48 0,36 <1 39,8 <0.1 0,02 0,04 0,13 0,08 0,3 0,12 0,03 1 <0.1 0,01 <0.005 <0.05 0,4 0,01 72,9 3 <10 31 52 0,6 1 <5 4,4 19 1,2 <1 <2 1,6 1,75 0,55 1 73,3 0,1 0,15 <0.01 0,71 0,46 2,1 0,84 0,07 1 <0.1 0,08 <0.005 0,18 0,4 0,02 2,8 3 <10 11 46 0,2 1 <5 1,5 7 <0.2 <1 <2 0,7 0,71 0,77 1 43,2 0,1 0,03 0,01 0,25 0,1 0,6 0,28 0,04 1 2,2 0,01 <0.005 0,07 0,4 0,01 3,5 2 <10 31 37 0,4 1 <5 2,1 12 <0.2 <1 <2 0,8 0,92 3,52 <1 50,9 0,1 0,05 0,02 0,35 0,2 1,1 0,28 0,04 1 1 0,02 <0.005 <0.05 0,3 0,01 4,7 3 <10 26 39 0,2 1 <5 1,6 6 <0.2 <1 3 0,7 0,7 0,3 1 47,8 <0.1 0,03 0,03 0,23 0,15 0,7 0,33 0,03 1 1,5 0,04 <0.005 <0.05 0,6 0,01 49 Ag Cd Li Mo Tl Ge In Re <0.5 <0.5 <10 <1 <0.02 <5 <0.005 <0.001 <0.5 <0.5 <10 <1 <0.02 <5 <0.005 <0.001 <0.5 <0.5 <10 <1 <0.02 <5 <0.005 <0.001 <0.5 <0.5 <10 <1 <0.02 <5 <0.005 <0.001 <0.5 <0.5 <10 <1 <0.02 <5 <0.005 <0.001 <0.5 <0.5 <10 <1 <0.02 <5 <0.005 <0.001 La Ce Pr Nd Sm Eu Gd Tb Dy Ho Tm Yb Lu 2,1 3,5 0,42 1,6 0,26 0,04 0,24 0,03 0,17 0,03 0,03 0,08 0,01 1,4 2 0,21 0,9 0,14 <0.03 0,12 0,02 0,13 0,02 0,03 0,09 0,01 6,5 12,4 1,5 5,5 0,97 0,19 0,84 0,15 0,71 0,17 0,07 0,44 0,06 2,6 4,3 0,47 1,6 0,3 0,05 0,28 0,03 0,25 0,04 0,04 0,12 0,02 2 3,2 0,38 1,6 0,3 0,04 0,28 0,05 0,35 0,08 0,04 0,23 0,03 2,1 3,2 0,39 1,4 0,25 0,04 0,33 0,03 0,23 0,04 0,03 0,11 0,02 50