Bulletin Mineralogie Petrologie

Dolníček Zdeněk, Ulmanová Jana

Volume 27, issue 2 (2019), pages 331-345

Alpine-type veins, chlorite, monazite, allanite, bastnäsite, chemical composition, chlorite geothermometry, Kutná Hora unit, Bohemian Massif

Two types of hydrothermal veins containing REE minerals were found in an abandoned quarry at Vrbčany. Steeply dipping veins cut migmatitized gneisses of the Kutná Hora Crystalline Complex. The Alpine-type veins are formed by quartz, chlorite (thuringite-chamosite) and muscovite, whereas another type of vein is dominated by quartz and pyrite accompanied by accessory chalcopyrite and K-feldspar. Chlorite geothermometry indicates crystallization of paragenetically old chlorite between 380 and 330 °C. Grains of REE minerals (monazite, allanite and rarely also bastnäsite) disseminated in quartz gangue exhibit identical textural features and chemical composition in both vein types. All REE minerals are characterized by low extent of fractionation of REE (La_N/Sm_N = 2.04 - 4.98), suggesting low contents of strong REE-complexing ligands in the parent fluids. The evolution of Eu anomalies of REE minerals (always negative in older monazite and bastnäsite, both negative and positive in younger allanite) indicates a decrease of temperature to ~200 °C and/or an increase of Eh during crystallization of the vein. The nature of both studied mineralizations corresponds to the Alpine-type veins with low content of calcium. A main source of mineral-forming components can be suggested in the host rocks. However, chemical composition of allanite, chlorite and pyrite (containing “exotic” components including Ca, NH₄, Ni and Co) implies for regional circulation of parent fluids involving also other rock types of the Kutná Hora Crystalline Complex as well as its cover formations. Very suitable conditions for mobilization of REE and subsequent crystallization of REE minerals can be assumed during formation of the quartz-pyrite vein because of the increased quantity of REE minerals (especially monazite) in the vein fill, which exceeds common accessory occurrence. Younger activity of hydrothermal and probably also supergene fluids is evidenced by alteration of chemical composition and partial dissolution of part of grains of REE minerals.

Abstract (PDF) - 174.77KB
Fulltext (PDF) - 2.66MB

Anders E, Grevesse N (1989) Abundances of the elements: Meteoritic and solar. Geochim Cosmochim Acta 53: 197-214

Bau M (1991) Rare-earth element mobility during hydrothermal and metamorphic fluid-rock interaction and the significance on the oxidation state of europium. Chem Geol 93: 219-230

Bau M, Möller P (1992) Rare earth element fractionation in metamorphogenic hydrothermal calcite, magnesite and siderite. Miner Petrol 45: 231-246

Bayliss P (1975) Nomenclature of the trioctahedral chlorites. Can Mineral 13:178-180

Bernard JH (1981) Minerály alpských žil a jim podobných asociací. In: Bernard JH, Čech F, Dávidová Š, Dudek A, Fediuk F, Hovorka D, Kettner R, Koděra M, Kopecký L, Němec D, Paděra K, Petránek J, Sekanina J, Staněk J, Šímová M: Mineralogie Československa: 405-419. Academia Praha

Bottrell SH, Carr LP, Dubessy J (1988) A nitrogen-rich metamorphic fluid and coexisting minerals in slates from North Wales. Mineral Mag 52: 451-457

Cathelineau M (1988) Cation site occupancy in chlorites and illites as a function of temperature. Clay Miner 23: 471-485

Čopjaková R, Novák M, Franců E (2011) Formation of authigenic monazite-(Ce) to monazite-(Nd) from Upper Carboniferous graywackes of the Drahany Upland: Roles of the chemical composition of host rock and burial temperature. Lithos 127: 373-385

Čopjaková R, Škoda R (2006) Detritické a autigenní REE minerály v sedimentech kulmu Drahanské vrchoviny, jejich význam pro studium provenience klastického materiálu a procesů diagenese. Acta Mus Moraviae, Sci Geol 91: 105-127

Dolníček Z, Nepejchal M, Kapusta J, Ulmanová J, Fojt B (2018) Primární zlatonosná mineralizace v Andělském údolí u Starého Města pod Sněžníkem. Bull Mineral Petrolog 26: 12-27

Dolníček Z, Ulmanová J (2018a) Texturně neobvyklá Cu sulfidická mineralizace a doprovodné minerály z alpské žíly od Markovic u Čáslavi. Bull Mineral Petrolog 26: 78-89

Dolníček Z, Ulmanová J (2018b) Revize sulfidické mineralizace z alpských žil od Markovic u Čáslavi (kutnohorské krystalinikum): minerální asociace a chemické složení. Bull Mineral Petrolog 26: 138-148

Dolníček Z, Ulmanová J (2019) Minerální asociace a chemické složení chloritů z alpských žil od Markovic u Čáslavi (kutnohorské krystalinikum). Bull Mineral Petrolog 27: 212-220

Dolníček Z, Ulmanová J, Sejkora J, Škácha P (2019) Nerudní minerály Au-Ag-Sb-Bi-Te mineralizace z ložiska Bytíz, příbramský rudní revír. Sborník abstraktů Otevřeného kongresu České geologické společnosti a Slovenskej geologickej spoločnosti, Beroun 3.-6. 9. 2019: 20

Filip J, Houzar S, Sulovský P (2002) Allanit a produkty jeho přeměny z pegmatitu a ze skarnu u Rešic, západní Morava. Acta Mus Moraviae, Sci geol 87: 87-101

Fišera M (1977) Geologie a petrografie kutnohorského krystalinika západně od Kolína. Výzk práce Ústř úst geol 16: 19-31

Fišera M (2000) Alpská parageneze - klasifikace, typy a naleziště v České republice. Bull mineral-petrolog Odd Nár Muz (Praha) 8: 23-40

Gieré R, Sorensen SS (2004) Allanite and other REE-rich epidote-group minerals. Rev Mineral Geochem 56: 431-493

Koutek J (1933) Geologie posázavského krystalinika I. (Okolí Rataj n. Sáz.). Věst Geol úst ČSR 9: 319-331

Kratochvíl J (1964) Topografická mineralogie Čech VII (U-Ž). Nakladatelství ČSAV. Praha

Lee SG, Lee DH, Kim Y, Chae BG, Kim WY, Woo NCh (2003) Rare earth elements as indicators of groundwater environment changes in a fractured rock system: evidence from fracture - filling calcite. Appl Geoch 18: 135-143

Liard J (1988) Chlorites: metamorphic petrology. In: Bailey SW (ed) Hydrous phyllosilicates. Reviews in Mineralogy 19: 405-447

Mastíková E (2011) Mineralogie a podmínky vzniku vybraných mineralizací v lomu Pohled (moldanubikum). MS, diplomová práce, PřF UP v Olomouci

Maydagán L, Franchini M, Impiccini A, Lentz D (2016) Phyllosilicates geochemistry and distribution in the Altar porphyry Cu-(Au) deposit, Andes Cordillera of San Juan, Argentina: Applications in exploration, geothermometry, and geometallurgy. J Geoch Explor 167: 83-109

McLennan SM (1989) Rare earth elements in sedimentary rocks: influence of provenance and sedimentary processes. Rev mineral 21: 169-200

Melka K (1965) Návrh na klasifikaci chloritových minerálů. Věst Ústř Úst geol 40: 23-27

Novotný P, Zimák J (2000) Thorit, monazit, allanit a další minerály z albitové žíly u Vernířovic (severní Morava). Bull mineral-petrogr odd Nár muz v Praze 8: 211-212

Oelkers EH, Poitrasson F (2002) An experimental study of the dissolution stoichiometry and rates of a natural monazite as a function of temperature from 50 to 230 °C and pH from 1.5 to 10. Chem Geol 191: 73-87

Petrík I, Broska I, Lipka J, Siman P (1995) Granitoid allanite-(Ce) substitution relations, redox conditions and REE distributions (on an example of I-type granitoids, Western Carpathians, Slovakia). Geol Carpath 46: 79-94

Pouchou JL, Pichoir F (1985) “PAP” (φρZ) procedure for improved quantitative microanalysis. In: Armstrong JT (ed.) Microbeam Analysis: 104-106. San Francisco Press, San Francisco

Rieder M, Cavazzini G, D´yakonov YS, Kamenetskii VAF, Gottardi G, Guggenheim S, Koval´ PV, Mueller G, Neiva AMR, Radoslovich EW, Robert JL, Sassi FP, Takeda H, Weiss Z, Wones DR (1998) Nomenclature of micas. Canad Mineral 36: 905-912

Schandl ES, Gorton MP (2004) A textural and geochemical guide to the identification of hydrothermal monazite: criteria for selection of samples for dating epigenetic hydrothermal ore deposits. Econ Geol 99: 1027-1035

Sverjensky DA (1984) Europium redox equilibria in aqueous solution. Earth Planet Sci Lett 67: 70-78

Synek J, Oliveriová D (1993) Terrane character of the north-east margin of the Moldanubian Zone: the Kutná Hora Crystalline Complex, Bohemian Massif. Geol Rundsch 82: 566-582

Šamánková M (2012) Mineralogické studium alpské parageneze z lomu u Libodřic. MS, dipl. práce, ÚGV PřF MU Brno

Števko M, Uher P, Ondrejka M, Ozdín D, Bačík P (2014) Quartz-apatite-REE phosphates-uraninite vein mineralization near Čučma (eastern Slovakia): a product of early Alpine hydrothermal activity in the Gemeric Superunit, Western Carpathians. J Geosci 59: 209-222

Taylor RD (2015) Orogenic gold formation and tectonic evolution of the Grass Valley gold district and temporal correlations of gold deposits in California. MS, unpublished PhD thesis, Colorado School of Mines, Golden. 149 pp

Wang KY, Qing M, Sun FY (2010) Study on the geochemical characteristics of ore-forming fluids and genesis of Xiaoxinancha gold-copper deposit, Jilin Province. Acta Petrol Sin 26: 3727-3734

Wang Y, Wang K, Konare Y (2018) N2-rich fluid in the vein type Yangjingou scheelite deposit, Yanbian, NE China. Sci Reports 8, Article No. 5662

Wiewióra A, Weiss Z (1990) Crystallochemical classifications of phyllosilicates based on the unified system of projection of chemical composition: II. The chlorite group. Clay Miner 25: 83-92

Wood SA (1990) The aqueous geochemistry of rare earth elements and yttrium. 2. Theoretical predictions of speciation in hydrothermal solutions to 350°C at saturated water pressure. Chem Geol 88: 99-125

Zhu XK, OʼNions RK (1999) Monazite chemical composition: some implications for monazite geochronology. Contrib Mineral Petrol 137: 351-363

Ziegler V (1982) Mineralogie Kolínska. Informační zpravodaj okresního aktivu státní ochrany přírody při odboru kultury ONV v Kolíně 4: 1-3

Zimák J, Novotný P (2002) Minerály vzácných zemin na hydrotermálních žilách v kulmu Nízkého Jeseníku a Oderských vrchů. Čas Slez Muz Opava (A) 51: 179-182

www1: www.geology.cz/svet-geologie/vylety/vylety/vychazka_VELKA_STRAZ_web.pdf (přístup z 16. 8. 2019)