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Spatial and temporal evolution of hydrothermal alteration at Lavras do sul, Brazil: Evidence from dioctahedral clay minerals

Published online by Cambridge University Press:  01 January 2024

Everton Marques Bongiolo*
Affiliation:
CPRM, Geological Survey of Brazil, Rua Banco da Província 105, 90840-030, Porto Alegre, RS, Brasil Universidade Federal do Rio Grandedo Sul, UFRGS, Instituto de Geociências, Av. Bento Gonçalves 9500, 91509-900, Porto Alegre, RS, Brazil
Patricia Patrier-Mas
Affiliation:
Université de Poitiers, CNRS, HYDRASA, 40 Avenue du Recteur Pineau, 86022 Poitiers, France
André Sampaio Mexias
Affiliation:
Universidade Federal do Rio Grandedo Sul, UFRGS, Instituto de Geociências, Av. Bento Gonçalves 9500, 91509-900, Porto Alegre, RS, Brazil
Daniel Beaufort
Affiliation:
Université de Poitiers, CNRS, HYDRASA, 40 Avenue du Recteur Pineau, 86022 Poitiers, France
Milton Luiz Laquintinie Formoso
Affiliation:
Universidade Federal do Rio Grandedo Sul, UFRGS, Instituto de Geociências, Av. Bento Gonçalves 9500, 91509-900, Porto Alegre, RS, Brazil
*
* E-mail address of corresponding author: [email protected]
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Abstract

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TheAu-Cu (±Pb, Zn, Ag) prospects of Lavras do Sul, southernmost Brazil, arehosted in Neoproterozoic granitic and volcanogenic rocks. Mineralization occurs in structurally controlled N40°W to E-W quartz veins; sericite (±chlorite) and sulfides are the main secondary minerals in associated wall rocks.

In the present contribution we use petrography (optical microscopy and scanning electron microscopy (SEM)), mineralogy (X-ray diffraction (XRD) with polytypes, FWHM, decomposition of diffraction patterns), and crystal chemistry of samples from several prospects to document the spatial and temporal evolution of sericitic alteration of veins and wall rocks associated with gold.

Hexagonal, coarse-grained 2M1 phengite-rich alteration (± illite) is best developed with coarse-grained primary growth (comb) quartz + pyrite ± Au veins and altered wall rock from the western portion of the granitic complex (phyllic alteration). Pure phengite was recognized by narrow XRD profiles (FWHM ⩽ 0.2°2θ CuKα) of the <5 µm particle-size fraction, non-expandable d001 X-ray reflections and interlayer charge (IC) >0.9 per O10(OH)2.

Towards the eastern zones of the granitic complex and in the volcanogenic rocks, wider XRD profiles (FWHM values ⩾ 0.2°2θ CuKα) were decomposed. They contain mixtures of coarse- to fine-grained, lath-like crystals of both 2M1 and 1M illite (non-expandable d001 X-ray reflections, IC between 0.85 and 0.89 per O10(OH)2) with expandable d001 reflections associated with lath-like, fine-grained crystals of ordered (R ⩾ 1) illite-rich I-S (80–90% of illite; IC of ∼0.8 per O10(OH)2), and minor amounts of regularly ordered (R = 1), illite-rich I-S mixed layers (75% of illite; IC of ∼0.74 per O10(OH)2). The dioctahedral clay association of illite + illite-rich I-S mixed layers (intermediate argillic alteration) is best developed in quartz + pyrite ± Au veins, breccias, and wall-rock alteration from the eastern portion of the granitic complex and in the volcanic area. Quartz from veins and breccias has fine-grained primary growth, recrystallization, and replacement textures, similar to those in epithermal deposits.

The overall distribution of the dioctahedral clays indicates that the study area represents a fracture-controlled, tilted, porphyry to epithermal deposit, with telescoping alteration features observed in the east of the mining district. Deeper levels of exposure of a large hydrothermal system are observed in the west of the mining district, as shown by higher-rank dioctahedral minerals (phengite) that crystallize at relatively high temperatures (Tphe ≈ 300°C, phyllic alteration) associated with coarse-grained, primary-growth quartz veins, similar to those observed in porphyry deposits. On the other hand, shallower levels of exposure are observed in the east of the study area, associated with abundant, lower-rank dioctahedral clay minerals (illite + illite-rich I-S mixed layers, intermediate argillic alteration) that crystallize at relatively lower temperatures (TI-S ≈ 120–200°C).

Available data show that gold is associated with phengite, but that lower-rank, overprinting alteration characterized by illite-I-S may have locally modified the original gold grades.

Type
Research Article
Copyright
Copyright © 2008, The Clay Minerals Society

References

Babinski, M. Chemale, F. Jr. Hartmann, L.A. Van Schmus, W.R. and Silva, L.C., 1996 Juvenile accretion at 750–700 Ma in southern Brazil Geology 24 439442.2.3.CO;2>CrossRefGoogle Scholar
Beane, R.E. and Titley, S.R., 1982 Hydrothermal alteration in silicate rocks, southwestern North America Advances in Geology of the Porphyry Copper Deposits Tucson, Arizona SNA University of Arizona Press 117137.Google Scholar
Beaufort, D. Westercamp, D. Legendre, O. and Meunier, A., 1990 The fossil hydrothermal system of Saint Martin, Lesser Antilles: Geology and lateral distribution of alterations Journal of Volcanology and Geothermal Research 40 219243.CrossRefGoogle Scholar
Bish, D.L. Reynolds, R.C. Jr., Bish, D.L. and Post, J.E., 1989 Sample preparation for X-ray diffraction Modern Powder Diffraction Washington, D.C Mineralogical Society of America 7399.CrossRefGoogle Scholar
Bongiolo, E.M., 2007 Integração dedados mineralógicos, isótopos estáveis (O, H) eporosidade de rochas (14C-PMMA) no reconhecimento da evolução da alteração no sistema hidrotermal de Lavras do Sul/RS, Brasil UFRGS, Brazil Porto Alegre 189 pp.Google Scholar
Bouchet, A., Meunier, A., and Sardini, P. (2001) Minéraux argileux — structures cristallines — identification par diffraction de rayons X. With CD-ROM. TotalFinaElf Editions, 136 pp.Google Scholar
Bril, H. Papapanagiotou, P. Patrier, P. Lenain, J.F. and Beaufort, D., 1996 Fluid-rock interaction in the geothermal field of Chipilapa (El Salvador): Contribution of fluid inclusion data European Journal of Mineralogy 8 515531.CrossRefGoogle Scholar
Chemale, F. Jr. Hartmann, L.A. and Silva, L.C., 1995 Stratigraphy and tectonism of Brasiliano Cycle in southern Brazil Communications of Geological Survey of Namibia 10 151166.Google Scholar
Creasey, S.C., 1959 Some phase relations in hydrothermally altered rock of porphyry copper deposits Economic Geology 54 351373.CrossRefGoogle Scholar
De Liz, J.D. Lima, E.F. Nardi, L.V.S. Hartmann, L.A. Sommer, C.A. and Goncalves, C.R.H., 2004 Aspectos petrográficos ecomposicionais do sistema multi-intrusivo da associação shoshonítica Lavras do Sul (RS) e seu potencial para mineralizações de ouro e sulfetos Revista Brasileira de Geociências 34 539552.CrossRefGoogle Scholar
Drits, V.A. and McCarty, D.K., 1996 The nature of diffraction effects from illite and illite-smectite consisting of inter-estratified trans-vacant and cis-vacant 2:1 layers: A semiquantitative technique for determination of layer-type content American Mineralogist 81 852863.CrossRefGoogle Scholar
Dowling, K. and Morrison, G.W., 1989 Application of quartz textures to the classification of gold deposits using North Queensland examples Economic Geology Monograph 6 342355.Google Scholar
Essene, E.J. and Peacor, D.R., 1995 Clay mineral thermometry. A critical perspective Clays and Clay Minerals 43 540553.CrossRefGoogle Scholar
Flexser, S., 1991 Hydrothermal alteration and past and present thermal regimes in the western moat of Long Valley caldera Journal of Volcanology and Geothermal Research 48 303318.CrossRefGoogle Scholar
Franchini, M. Impiccini, A. Meinert, L. Grathoff, G. and Schalamuk, I.B.A., 2007 Clay mineralogy and zonation in the Campana Mahuida porphyry Cu deposit, Neuquén, Argentina: implications for porphyry Cu exploration Economic Geology 102 2754.CrossRefGoogle Scholar
Gastal, M.C.P. and Lafon, J.M., 1998 Gênese e evolução dos granitóides metaluminosos de afinidade alcalina da porção oeste do escudo Sul-riograndense: Geoquímica eisótopos de Rb-Sr ePb-Pb Revista Brasileira de Geociências 28 1128.CrossRefGoogle Scholar
Gastal, M.C.P., Lafon, J.M., and Koester, E. (2003) Sr-Nd-Pb isotopes for minettes and granitoids from the Lavras do Sul Intrusive Complex, RS. Pp. 564567 in: IV South American Symposium on Isotope Geology, Salvador, Short Papers, 2.Google Scholar
Harvey, C.C. and Browne, P.R.L., 1991 Mixed-layer clay geothermometry in the Wairakei Geothermal Field, New Zealand Clays and Clay Minerals 39 614621.CrossRefGoogle Scholar
Hedenquist, J.W. Arribas, A. Jr. and Reynolds, T.J., 1998 Evolution of an intrusion-centered hydrothermal system: Far Southeast-Lepanto porphyry and epithermal Cu-Au deposits, Philippines Economic Geology 93 373404.CrossRefGoogle Scholar
Horton, D.G., 1985 Mixed-layer illite/smectite as a paleo-temperature indicator in the Amethyst vein system, Creede District, Colorado, USA Contributions to Mineralogy and Petrology 91 171179.CrossRefGoogle Scholar
Inoue, A. and Velde, B., 1995 Formation of clay minerals in hydrothermal environments Origin and Mineralogy of Clays New York Springer-Verlag 268329.CrossRefGoogle Scholar
Jin, Z. Zhu, J. Ji, J. Li, F. and Lu, X., 2002 Two origins of illite at the Dexing porphyry Cu deposit, East China: implications for ore-forming fluid constraint on illite crystallinity Clays and Clay Minerals 50 381387.Google Scholar
Kaul, P.F.T. and Rheinheimer, D., 1974 Projeto Ouro no Rio Grande do Sul e Santa Catarina Brazil Relatório Final em Convênio CPRM/DNPM 290 pp.Google Scholar
Lanson, B., 1997 Decomposition of experimental X-ray diffraction patterns (profile fitting). A convenient way to study clay minerals Clays and Clay Minerals 45 132146.CrossRefGoogle Scholar
Lanson, B. and Besson, G., 1992 Characterization of the end of smectite-to-llite transformation; decomposition of X-ray patterns Clays and Clay Minerals 40 4052.CrossRefGoogle Scholar
Lanson, B. and Champion, D., 1991 The I-S-to-illite reaction in the late stage diagenesis American Journal of Science 291 473596.CrossRefGoogle Scholar
Lima, E.F. and Nardi, L.V.S., 1998 The Lavras do Sul Shoshonitic association: implications for origin and evolution of neoproterozoic shoshonitic magmatism in southernmost Brazil Journal of South American Earth Sciences 11 6777.CrossRefGoogle Scholar
Lowell, J.D. and Guilbert, J.M., 1970 Lateral and vertical alteration — mineralization zoning in porphyry ore deposits Economic Geology 69 373408.CrossRefGoogle Scholar
Mas, A. Patrier, P. Beaufort, D. and Genter, A., 2003 Clay-mineral signatures of fossil and active hydrothermal circulations in the geothermal system of the Lamentin Plain, Martinique Journal of Volcanology and Geothermal Research 124 195218.CrossRefGoogle Scholar
Merriman, R.J. Peacor, D.R., Frey, M. and Robinson, D., 1999 Very low grade metapelites: mineralogy, microfabrics and measuring reaction progress Low-grade Metamorphism Oxford, UK Blackwell Publishing 1060.Google Scholar
Meunier, A., 2003 Argiles Paris CPI-GB Science Publisher 433 pp.Google Scholar
Meunier, A. and Velde, B., 1989 Solid solutions in I-S mixed-layer minerals and illite American Mineralogist 74 11061112.Google Scholar
Meunier, A. and Velde, B., 2004 Illite: Origins, Evolution, and Metamorphism Berlin Springer-Verlag 286 pp.CrossRefGoogle Scholar
Mexias, A.S. Formoso, M.L.L. Meunier, A. and Beaufort, D., 1990 O sistema hidrotermal fóssil de Volta Grande — Lavras do Sul/RS. ParteI — Petrografia do hidrotermalismo Geochimica Brasiliensis 4 139157.Google Scholar
Mexias, A.S. Berger, G. Gomes, M.E.B. Formoso, M.L.L. Dani, N. Frantz, J.C. and Bongiolo, E.M., 2005 Geochemical modelling of gold precipitation conditions in the Bloco do Butiá Mine, Lavras do Sul/Brazil Anais da Academia Brasileira de Geociências 77 3 112.Google ScholarPubMed
Nadeau, P.H. and Reynolds, C.R., 1981 Burial and contact metamorphism in the Mancos Shale Clays and Clay Minerals 29 249259.CrossRefGoogle Scholar
Nardi, L.V.S., 1984 Geochemistry and petrology of the Lavras Granite Complex, RS, Brazil UK Department of Geology, University of London 268 pp.Google Scholar
Nardi, L.V.S. Lima, E.F., Holz, M. and DeRos, L.F., 2000 O magmatismo shoshonítico ealcalino da Bacia do Camaquã — RS Geologia e Estratigrafia do Rio Grande do Sul Porto Alegre, Brazil Editora Gráfica da UFRGS 119131.Google Scholar
Norton, D. and Knight, J., 1977 Transport phenomena in hydrothermal systems: cooling plutons American Journal of Science 277 937981.CrossRefGoogle Scholar
Parry, W.T. Jasumback, M. and Wilson, P.N., 2002 Clay mineralogy of phyllic and intermediate argillic alteration at Bingham, Utah Economic Geology 97 221239.CrossRefGoogle Scholar
Patrier, P. Papapanagiotou, P. Beaufort, D. Traineau, H. Bril, H. and Rojas, J., 1996 Role of permeability versus temperaturein the distribution of the fine (<0.2 µm) clay fraction in the Chipilapa geothermal system (El Salvador) Journal of Volcanology and Geothermal Research 72 101120.CrossRefGoogle Scholar
Reischl, J.L., 1980 Mineralizaçõesauríferas associadas ao Complexo Granítico Lavras do Sul - RS Congresso Brasileiro de Geologia 32 Brazil Camboriú, Anais 7001712.Google Scholar
Reischl, J.L., 1998 Diagnóstico do potencial mineral do município de Lavras do Sul/RS. Public repport Brazil Minerar Consultoria e Projetos Ltda, 1 CD-ROM.Google Scholar
Remus, M.V.D. Hartmann, L.A. McNaughton, N.J. and Groves, D.I., 2000 Distal magmatic-hydrothermal origin for theCamaquã Cu (Au-Ag) and Santa Maria Pb, Zn (Cu-Ag) Deposits, Southern Brazil Gondwana Research 3 155174.CrossRefGoogle Scholar
Reyes, A.G., 1990 Petrology of the Philippine geothermal systems and the application of alteration mineralogy to their assessment Journal of Volcanology and Geothermal Research 43 279309.CrossRefGoogle Scholar
Reynolds, R.C. (1980) Interstratified minerals. Pp. 249274 in: Crystal Structures of Clay Minerals and their X-ray Identification (Brindley, G.W. and Brown, G., editors). Monograph 5, Mineralogical Society of London.CrossRefGoogle Scholar
Reynolds, R.C., 1985 Description of program NEWMOD for the calculation of one-dimensional X-ray diffraction patterns of mixed-layered clays Hanover, New Hampshire, USA Department of Earth Sciences, Dartmouth College.Google Scholar
Ribeiro, M., 1983 Informes sobre a Formação Maricá Iheringia, Série Geologia 9 350.Google Scholar
Sasada, M., 2000 Igneous-related active geothermal system versus porphyry copper hydrothermal system Proceedings of the World Geothermal Congress Japan Kyushu-Tohoku 16911693.Google Scholar
Simmons, S.F. Arehart, G. Simpson, M.P. and Mauk, J.L., 2000 Origin of massive calcite in the Golden Cross Low-sulphidation, epithermal Au-Ag Deposit, New Zealand Economic Geology 95 99112.CrossRefGoogle Scholar
środoń, J. Elsass, F. McHardy, W.J. and Morgan, D.J., 1992 Chemistry of illite/smectite inferred from TEM measurements of fundamental particles Clay Minerals 27 137158.CrossRefGoogle Scholar
Tillick, D.A. Peacor, D.R. and Mauk, J.L., 2001 Genesis of dioctahedral phyllosilicates during hydrothermal alteration of volcanic rocks: I. The Golden Cross epithermal ore deposit, New Zealand Clays and Clay Minerals 49 126140.CrossRefGoogle Scholar
Titley, S.R. and Titley, S.R., 1982 The style and progress of mineralization and alteration in porphyry copper systems Advances in Geology of the Porphyry Copper Deposits, southwestern North America Tucson, Arizona University of Arizona Press 93166.Google Scholar
Velde, B., 1985 Clay Minerals: a Physico-Chemical Explanation of their Occurrence Amsterdam Elsevier 427 pp.Google Scholar