Evolution of clay mineral assemblages in the Tinguiririca geothermal field, Andean Cordillera of central Chile: an XRD and HRTEM-AEM study
Author
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Vásquez, M.
Author
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Nieto, F.
es_CL
Author
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Morata Céspedes, Diego
es_CL
Author
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Droguett, B.
es_CL
Author
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Carrillo Rosua, F. J.
es_CL
Author
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Morales, S.
es_CL
Admission date
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2014-12-29T15:25:11Z
Available date
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2014-12-29T15:25:11Z
Publication date
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2014
Cita de ítem
dc.identifier.citation
Evolution of clay mineral assemblages in the Tinguiririca geothermal field, Andean Cordillera of central Chile: an XRD and HRTEM-AEM study
en_US
Identifier
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https://repositorio.uchile.cl/handle/2250/126823
General note
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Artículo de publicación ISI
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Abstract
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HRTEM textural evidence shows that clay minerals in the Tinguiririca geothermal field (Andean Cordillera, central
Chile) are the result of direct alteration of former volcanic glass and minerals by hydrothermal fluids at similar
temperatures to the present day. They show the classical pattern of diagenetic transformation from smectite
at the top to illite at the bottom, with the progressive formation of corrensite and chlorite. The high fluid/rock
ratio, disposability of necessary cations and absence of previous detrital phyllosilicates allow the consideration
of this area as a natural laboratory to establish the extreme ideal conditions for very low-T reactions. Transformations
from smectite to R1 illite–smectite (I–S) and from these to R3 mixed-layers occur respectively at 80–120 °C
and 125–180 °C. In spite of ideal genetic conditions, the new-formed minerals show all the defective character
and lack of textural and chemical equilibriumpreviously described in the literature for diagenetic and hydrothermal
low-temperature assemblages. Chemistry of smectite–illite phases evolves basically through a diminution of
the pyrophyllitic component toward a theoreticalmuscovite (Si4++□-> Al3++K+). However, a second chemical
vector (Si4++Mg2+→Al3++Al3+), that is, decreasing of the tschermack component, also contributes to the
evolution toward the less Si-more Al rich muscovite in relation to the original smectite. Residual Mg (and Fe)
from the latter reaction is consumed in the genesis of chloritic phases. Nevertheless, as a consequence of the
lack of chemical equilibrium (probably because of the short time-scale of the geothermal alteration processes),
the composition of clay minerals is highly heterogeneous at the level of a single sample. Consequently, the respective
fields of smectite, R1 I–S and R3 I–S overlap each other,making the distinction among these three phases
impossible based exclusively on chemical data.
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Patrocinador
dc.description.sponsorship
Authors thank Energia Andina company and, especially German
Pineda and Richard Sutil, for the facilities in the access to the Pte-1 borehole
samples. We also thank M.M. Abad (CIC, University of Granada) for
her help with the HRTEM work. Financial support was provided by the
Chilean Research Projects Fondecyt-Regular-1140629 and FONDAPCONICYT-
15090013 “Andean Geothermal Center of Excellence (CEGA)”.
We are grateful toM. Do Campo for her help in the calculation of chlorite
geothermometry. Lucy McGee is acknowledged for reviewing the English.
Comments and suggestions from Dr. A. Inoue, Dr. J. Moore and an
anonymous referee strongly improved the previous version of the Ms.