J
2016
EXPERIMENTAL STUDY OF ANISOTROPY OF QUARTZ DISSOLUTION AND ITS ROLE IN FLUID MIGRATION IN ROCKS
BENEDOVÁ, Šárka and Jaromír LEICHMANN
Basic information
Original name
EXPERIMENTAL STUDY OF ANISOTROPY OF QUARTZ DISSOLUTION AND ITS ROLE IN FLUID MIGRATION IN ROCKS
Authors
BENEDOVÁ, Šárka (203 Czech Republic, belonging to the institution) and
Jaromír LEICHMANN (203 Czech Republic, guarantor, belonging to the institution)
Edition
Acta Geodynamica et Geomaterialia, Praha, Academy of Science of the Czech Republic, 2016, 1214-9705
Other information
Type of outcome
Článek v odborném periodiku
Field of Study
10500 1.5. Earth and related environmental sciences
Country of publisher
Czech Republic
Confidentiality degree
není předmětem státního či obchodního tajemství
Impact factor
Impact factor: 0.699
RIV identification code
RIV/00216224:14310/16:00093876
Organization unit
Faculty of Science
Keywords (in Czech)
Rozpouštění křemene, krystalové plochy, mechanické defekty, metasomatoza, alterace
Keywords in English
Quartz dissolution; Crystal faces; Mechanical defects; Metasomatism; Alteration
Tags
International impact, Reviewed
V originále
Quartz dissolution in hydrothermal-metasomatic processes is common feature in magmatic and metamorphic quartz rich rocks. This experimental work aims to compare the dissolution of individual quartz faces and to clarify the role of mechanical defects in quartz grain dissolution. Two types of experiments were made to define the dissolution anisotropy: hydrothermal experiments (quartz-distilled water) and chemical dissolution (quartz - 40 % hydrofluoric acid). Hydrothermal experiments using various types of quartz samples as well as chemical dissolution of quartz faces show that quartz dissolution is an anisotropic process. The solubility of rhombs is higher than that of prism faces. At lower temperatures the separated etch pits develop and with increasing temperature the etch pits start to link and the continuous striations (prisms) or overlapping arrows (rhombs) are observed. Such a surface structure may facilitate fluid migration through a solid rock. An experiment using a mechanically disrupted surface of the quartz crystal shows the decisive role of this defect on the dissolution. Fluid migration through rocks can then be strongly influenced for instance by brittle deformation, to which quartz with no cleavage is easily susceptible. Such defects additionally enhance fluid movement through rocks, which plays a decisive role during hydrothermal-metasomatic quartz dissolution.
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