scholarly journals Basalt - fluid interactions at subcritical and supercritical conditions: An experimental study

2021 ◽  
Author(s):  
◽  
Mauro Passarella
Keyword(s):  
Mineral Assemblage ◽  
Fluid Composition ◽  
Natural Seawater ◽  
Distilled Water ◽  
Exit Point ◽  
Secondary Mineral ◽  
Hydrothermal Conditions ◽  
Fluid Chemistry ◽  
Glass Dissolution ◽  
Geothermal Brine

<p><b>To investigate the interaction between fluids and basalt at subcritical, near-supercritical, and supercritical hydrothermal conditions (350-400˚C/500 bar), eight experiments have been conducted. These used a continuous-flow, high temperature and pressure hydrothermal apparatus. The basalt was reacted with three fluids: distilled water; geothermal brine; and natural seawater. Two further experiments used only seawater as a control to determine its behaviour without the influence of basalt.</b></p> <p> With distilled water, the fluid chemistry results show elevated SiO2, K, Cl, SO4, and H2S in solution for the first 12 days of both experiments. This is due to volcanic glass dissolution. After glass was removed, fluid composition was controlled by the remaining rock minerals. At 400˚C, the secondary mineral assemblage at the bottom of the Reactor (fluid entry point) is composed of grossular, wollastonite, anorthite, and chlorite. These results show the effectiveness of distilled water, which lacks any alkali cations, at removing Na and K rapidly from the rock. At the top of the Reactor (fluid exit point) the secondary minerals are anorthite and celadonite. At 350˚C, the secondary mineral assemblage at the bottom is anorthite and chlorite, while celadonite is the dominant secondary mineral at the top. In both experiments, celadonite replaces solely olivine. The formation of celadonite through reaction with distilled water shows that it can be formed by the interaction of deuteric water and basalt without addition of other components.</p> <p> The geothermal brine contains high concentrations of SiO2, K, SO4, Na, Cl and has an acidic pH. At 400˚C, fluid chemistry displays elevated SiO2 concentrations for approximately two weeks due to glass dissolution. At 350˚C, SiO2 concentration is initially high after temperature increase, but decreases gradually over the remainder of the experiment. At 400˚C, the secondary mineral assemblage at the bottom of the Reactor is composed of anhydrite and biotite, while at the top of the Reactor, smectite is the only secondary mineral. At 350˚C, anhydrite and smectite are found at the bottom, while only smectite is found at the top. The lack of biotite at 350˚C suggests this mineral’s precipitation kinetics are too slow to outcompete chlorite precipitation.</p> <p> The seawater-only experiments were conducted as controls to determine its behaviour during heat-up and provide the input solution composition for the seawater-basalt experiments. Both seawater-only experiments (377˚C and 342˚C) show the precipitation of anhydrite, caminite and brucite due to their retrograde solubilities. The effluent solutions are greatly depleted in Ca, Mg and SO4.</p> <p> In the seawater-basalt experiments at near-supercritical (400˚C) and subcritical conditions (350˚C), elevated SiO2 concentrations due to glass dissolution are not observed. This is attributed to rapid secondary mineral precipitation. Fluid chemistry and mass balance calculations show almost complete removal of SO4, and in particular, Mg, from the seawater while Ca shows a considerable loss from the rock. Three mineralization fronts were identified: (1) glass dissolution; (2) chloritization; and (3) anhydrite precipitation. In both experiments, there is a switch from chloritization to smectitization. This is accompanied by a decrease in Mg/Fe ratio in smectite. This mineral was also found at the top of both experiments, but its composition was more reflective of the rock.</p> <p>In terms of reactivity, the order of phases from most to least reactive is glass – olivine – clinopyroxene – plagioclase – Fe-Ti oxide. For the aluminosilicate phases this is attributed their respective Al contents. The seawater-basalt experiments also emphasise the fast rate of reaction at which Mg is fixed by the rock, which is conjectured to take less than a few hours.</p> <p>Considering all experiments, the distilled water results show a rock control on fluid chemistry while in the remaining basalt experiments, the chemistry is largely controlled by the fluid.</p> <p>Temperatures calculated using standard Na/K geothermometer did not estimate, in most cases, values close to the experimental temperature. This is due to the inability of the rock to sufficiently adjust the Na/K ratio given the secondary mineral assemblages that form.</p> <p> </p>

scholarly journals Basalt - fluid interactions at subcritical and supercritical conditions: An experimental study

2021 ◽  
Author(s):  
◽  
Mauro Passarella
Keyword(s):  
Mineral Assemblage ◽  
Fluid Composition ◽  
Natural Seawater ◽  
Distilled Water ◽  
Exit Point ◽  
Secondary Mineral ◽  
Hydrothermal Conditions ◽  
Fluid Chemistry ◽  
Glass Dissolution ◽  
Geothermal Brine

<p><b>To investigate the interaction between fluids and basalt at subcritical, near-supercritical, and supercritical hydrothermal conditions (350-400˚C/500 bar), eight experiments have been conducted. These used a continuous-flow, high temperature and pressure hydrothermal apparatus. The basalt was reacted with three fluids: distilled water; geothermal brine; and natural seawater. Two further experiments used only seawater as a control to determine its behaviour without the influence of basalt.</b></p> <p> With distilled water, the fluid chemistry results show elevated SiO2, K, Cl, SO4, and H2S in solution for the first 12 days of both experiments. This is due to volcanic glass dissolution. After glass was removed, fluid composition was controlled by the remaining rock minerals. At 400˚C, the secondary mineral assemblage at the bottom of the Reactor (fluid entry point) is composed of grossular, wollastonite, anorthite, and chlorite. These results show the effectiveness of distilled water, which lacks any alkali cations, at removing Na and K rapidly from the rock. At the top of the Reactor (fluid exit point) the secondary minerals are anorthite and celadonite. At 350˚C, the secondary mineral assemblage at the bottom is anorthite and chlorite, while celadonite is the dominant secondary mineral at the top. In both experiments, celadonite replaces solely olivine. The formation of celadonite through reaction with distilled water shows that it can be formed by the interaction of deuteric water and basalt without addition of other components.</p> <p> The geothermal brine contains high concentrations of SiO2, K, SO4, Na, Cl and has an acidic pH. At 400˚C, fluid chemistry displays elevated SiO2 concentrations for approximately two weeks due to glass dissolution. At 350˚C, SiO2 concentration is initially high after temperature increase, but decreases gradually over the remainder of the experiment. At 400˚C, the secondary mineral assemblage at the bottom of the Reactor is composed of anhydrite and biotite, while at the top of the Reactor, smectite is the only secondary mineral. At 350˚C, anhydrite and smectite are found at the bottom, while only smectite is found at the top. The lack of biotite at 350˚C suggests this mineral’s precipitation kinetics are too slow to outcompete chlorite precipitation.</p> <p> The seawater-only experiments were conducted as controls to determine its behaviour during heat-up and provide the input solution composition for the seawater-basalt experiments. Both seawater-only experiments (377˚C and 342˚C) show the precipitation of anhydrite, caminite and brucite due to their retrograde solubilities. The effluent solutions are greatly depleted in Ca, Mg and SO4.</p> <p> In the seawater-basalt experiments at near-supercritical (400˚C) and subcritical conditions (350˚C), elevated SiO2 concentrations due to glass dissolution are not observed. This is attributed to rapid secondary mineral precipitation. Fluid chemistry and mass balance calculations show almost complete removal of SO4, and in particular, Mg, from the seawater while Ca shows a considerable loss from the rock. Three mineralization fronts were identified: (1) glass dissolution; (2) chloritization; and (3) anhydrite precipitation. In both experiments, there is a switch from chloritization to smectitization. This is accompanied by a decrease in Mg/Fe ratio in smectite. This mineral was also found at the top of both experiments, but its composition was more reflective of the rock.</p> <p>In terms of reactivity, the order of phases from most to least reactive is glass – olivine – clinopyroxene – plagioclase – Fe-Ti oxide. For the aluminosilicate phases this is attributed their respective Al contents. The seawater-basalt experiments also emphasise the fast rate of reaction at which Mg is fixed by the rock, which is conjectured to take less than a few hours.</p> <p>Considering all experiments, the distilled water results show a rock control on fluid chemistry while in the remaining basalt experiments, the chemistry is largely controlled by the fluid.</p> <p>Temperatures calculated using standard Na/K geothermometer did not estimate, in most cases, values close to the experimental temperature. This is due to the inability of the rock to sufficiently adjust the Na/K ratio given the secondary mineral assemblages that form.</p> <p> </p>

scholarly journals Fluid Chemistry of Mid-Ocean Ridge Hydrothermal Vents: A Comparison between Numerical Modeling and Vent Geochemical Data

Geofluids ◽  
2018 ◽  
Vol 2018 ◽  
pp. 1-20 ◽  
Author(s):  
Samuel Pierre ◽  
Alexander P. Gysi ◽  
Thomas Monecke
Keyword(s):  
Numerical Modeling ◽  
Geochemical Data ◽  
Fluid Composition ◽  
Secondary Mineral ◽  
Ambient Seawater ◽  
Mineral Solution ◽  
Mid Ocean Ridge ◽  
Activity Ratios ◽  
Proton Activity ◽  
Ocean Ridge

Seawater-basalt interaction taking place at mid-ocean ridges was studied using numerical modeling to determine the compositional evolution of hydrothermal fluids and associated alteration mineralogy forming within newly emplaced crustal material. Geochemical modeling was carried out in a closed seawater-basalt system at discrete temperature intervals between 2 and 400°C at 500 bars, varying fluid/rock ratios, and secondary mineral assemblages representative of basalt alteration in natural systems. In addition to temperature, the fluid/rock ratio has a fundamental control on the resulting system chemistry. At rock-buffered conditions (low fluid/rock ratios), the mineral-solution equilibrium was characterized by high cation to proton activity ratios foraCa2+/(aH+)2andaNa+/aH+and very low dissolved Mg concentrations due to the precipitation of smectites and chlorite. A complex secondary mineral alteration assemblage dominated by Ca- and Na-bearing minerals including zeolites, calcite, epidote, prehnite, clinozoisite, and albite was predicted to form. The resulting fluid composition was alkaline and reduced relative to ambient seawater, with Eh values ranging between −0.2 and −0.6 V. In contrast, seawater-buffered conditions (high fluid/rock ratios) resulted in lower cation to proton activity ratios foraCa2+/(aH+)2andaNa+/aH+and higher dissolved Mg concentrations comparable to the value of this element in ambient seawater. A more simple mineral assemblage was predicted to form at these conditions with the predominance of Al-Si- and Mg-bearing minerals including kaolinite, quartz, and talc in addition to large amounts of anhydrite. The resulting fluid composition was mildly acidic and oxidized relative to seawater with Eh values ranging between −0.2 and 0 V. These modeling results were compared to a compilation of submarine hydrothermal vent fluid compositions from mid-ocean ridge settings and analogous basalt-dominated environments. The agreement obtained between the simulations and the compiled fluid data indicates that mid-ocean ridge hydrothermal processes can be closely reproduced by mineral-solution equilibria for a broad range of temperatures and fluid/rock ratios.

Effects of Rocks and Backfill Materials on Waste Glass Leaching

1985 ◽  
Vol 50 ◽  
Author(s):  
K. Ishiguro ◽  
N. Sasaki ◽  
H. Kashihara ◽  
M. Yamamoto
Keyword(s):  
Waste Glass ◽  
Distilled Water ◽  
Leach Rate ◽  
Glass Dissolution ◽  
Crushed Granite ◽  
Backfill Materials ◽  
Long Term Experiment ◽  
Static Conditions ◽  
Glass Leaching

AbstractExtensive studies have been made on the interactions between a waste glass and repository materials under static conditions. One of the PNC reference glasses was leached in the solution prepared from water in contact with crushed granite, tuff, diabase and backfill materials such as bentonite and zeolite. The leachant solutions except for some bentonite solutions reduced the glass leach rate compared with that measured in distilled water. The extent of the reduction was a function of silicon concentration in solution. The bentonite solutions enhanced the glass dissolution rate by a factor of 2 to 3 at low bentonite/water ratios but the effect was found to be less important at high bentonite/water ratios and in the long-term experiment. Addition of granite and zeolite to the bentonite solutions decreased the leach rate below the value measured in distilled water.

Chloritization in Proterozoic granite from the Äspö Laboratory, southeastern Sweden: record of hydrothermal alterations and implications for nuclear waste storage

Clay Minerals ◽  
2011 ◽  
Vol 46 (3) ◽  
pp. 495-513 ◽  
Author(s):  
S. Morad ◽  
M. Sirat ◽  
M. A. K. El-Ghali ◽  
H. Mansurbeg
Keyword(s):  
Nuclear Waste ◽  
Reaction Mechanisms ◽  
Mineral Assemblage ◽  
Granitic Rocks ◽  
Chemical Characteristics ◽  
Fluid Composition ◽  
Fracture Permeability ◽  
Nuclear Waste Storage ◽  
Waste Storage ◽  
Basement Rocks

AbstractHydrothermal alteration of Proterozoic granitic rocks in the Äspö underground laboratory, southestern Sweden, resulted in the formation of chlorite with large variations in textural and chemical characteristics, which reflect differences in formation temperatures, fluid composition, and reaction mechanisms. The mineral assemblage associated with chlorite, including Ca-Al silicates (prehnite, pumpellyite, epidote, and titanite), Fe-oxides, calcite, albite and K-feldspar, suggests that chloritization occurred at temperatures of between 200–350°C during various hydrothermal events primarily linked to magmatism and rock deformation. Petrographic and electron microprobe analyses revealed that chlorite replaced biotite, amphibole and magnetite, and hydrothermal chlorite phases filled fractures and vugs in the granitic rocks. While fracture-filling chlorite reduces fracture permeability, chloritization reactions in the host granite resulted in the formation of new localized microporosity that should thus be taken into consideration when evaluating the safety of the granitic basement rocks as a repository for nuclear waste. It is also important to take into account that similar alteration reactions may occur at the site of stored nuclear waste where temperatures in excess of 100°C might be encountered.

scholarly journals The degradation of organic compounds impacts the crystallization of clay minerals and vice versa

2019 ◽  
Vol 9 (1) ◽  
Author(s):  
Pierre Jacquemot ◽  
Jean-Christophe Viennet ◽  
Sylvain Bernard ◽  
Corentin Le Guillou ◽  
Baptiste Rigaud ◽  
...  
Keyword(s):  
Electron Microscopy ◽  
Chemical Composition ◽  
Clay Minerals ◽  
Organic Compounds ◽  
Amorphous Silica ◽  
Mineral Assemblage ◽  
Laboratory Experiments ◽  
Fine Scale ◽  
Organic Fraction ◽  
Hydrothermal Conditions

AbstractExpanding our capabilities to unambiguously identify ancient traces of life in ancient rocks requires laboratory experiments to better constrain the evolution of biomolecules during advanced fossilization processes. Here, we submitted RNA to hydrothermal conditions in the presence of a gel of Al-smectite stoichiometry at 200 °C for 20 days. NMR and STXM-XANES investigations revealed that the organic fraction of the residues is no longer RNA, nor the quite homogeneous aromatic-rich residue obtained in the absence of clays, but rather consists of particles of various chemical composition including amide-rich compounds. Rather than the pure clays obtained in the absence of RNA, electron microscopy (SEM and TEM) and diffraction (XRD) data showed that the mineralogy of the experimental residues includes amorphous silica and aluminosilicates mixed together with nanoscales phosphates and clay minerals. In addition to the influence of clay minerals on the degradation of organic compounds, these results evidence the influence of the presence of organic compounds on the nature of the mineral assemblage, highlighting the importance of fine-scale mineralogical investigations when discussing the nature/origin of organo-mineral microstructures found in ancient rocks.

TEM Investigation of Epitaxial Assembly in Aggregates of BaTiO3 and CaTiO3 Nanocrystalline Particles Synthesized under Hydrothermal Conditions

2007 ◽  
Vol 1054 ◽  
Author(s):  
Naoki Iwaji ◽  
Hiromichi Takebe ◽  
Makoto Kuwabara
Keyword(s):  
Crystal Growth ◽  
Volume Ratio ◽  
Hydrothermal Condition ◽  
Distilled Water ◽  
Hydrothermal Conditions ◽  
Transmission Electron Microscopy Analysis ◽  
Transmission Electron ◽  
Nanocrystalline Particles ◽  
Electron Microscopy Analysis ◽  
Microscopy Analysis

ABSTRACTWe investigated epitaxial assembly in aggregates of BaTiO3 and CaTiO3 nanocrystals, which were synthesized under a hydrothermal condition at 150°C using distilled water-ethanol solvent, by transmission electron microscopy analysis. The volume ratio of distilled water-ethanol used as the solvent gives a significant influence on the crystal growth of the nanocrystals. The obtained results indicate that epitaxial assembly is surely involved in the crystal growth of BaTiO3 and CaTiO3 nanocrystals under the present thermal condition.

The effect of fluid composition on the mechanism of the aragonite to calcite transition

2008 ◽  
Vol 72 (1) ◽  
pp. 111-114 ◽  
Author(s):  
C. Perdikouri ◽  
A. Kasioptas ◽  
C. V. Putnis ◽  
A. Putnis
Keyword(s):  
Electron Microscopy ◽  
Mass Spectrometry ◽  
Fluid Composition ◽  
Hydrothermal Conditions ◽  
Precipitation Mechanism ◽  
X Ray ◽  
Inductively Coupled ◽  
Inductively Coupled Mass Spectrometry ◽  
Icp Ms ◽  
Scanning Electron

AbstractExperiments were performed to investigate the transformation of natural aragonite crystals to calcite by reaction with aqueous solutions of calcium carbonate at hydrothermal conditions for different periods of time. X-ray powder diffraction (XRD), scanning electron microscopy (SEM), Raman spectroscopy and Laser ablation inductively coupled mass spectrometry (LA-ICP-MS) were used to characterize the reaction product. The results indicate that the replacement of aragonite by calcite follows an interface-coupled dissolution-precipitation mechanism.

scholarly journals Coesite inclusion in diamondferous kyanite-bearing eclogite from kimberlite pipe Udachnaya (Siberian Craton)

2019 ◽  
Vol 487 (4) ◽  
pp. 428-431
Author(s):  
D. S. Mikhailenko ◽  
A. V. Korsakov ◽  
O. V. Rezvukhina ◽  
A. V. Golovin ◽  
N. V. Sobolev
Keyword(s):  
Siberian Craton ◽  
Mineral Assemblage ◽  
Kimberlite Pipe ◽  
Secondary Mineral ◽  
Metasomatic Alteration ◽  
Diamond Crystallization ◽  
Eclogite Xenolith

A find of coesite in a kyanite graphite-diamond-bearing eclogite xenolith from the Udachnaya-Vostochnaya kimberlite pipe is described in this paper. The coesite relics were found in intensely fractured garnet indicating some influence of the kimberlite melt, which is supported by the typical secondary mineral assemblage around this inclusion. These data indicate that shallower diamond-free coesite rocks (2,7 GPa) underwent metamorphism distinct from diamond-bearing coesite eclogites (~4 GPa). The metasomatic alteration of rock interacting with C-O-H fluid during diamond crystallization may be another possible reason for the missing coesite in diamond-bearing xenoliths.

scholarly journals Nuclear Melt Glass Dissolution and Secondary Mineral Precipitation at 40 to 200C

2004 ◽  
Author(s):  
M Zavarin ◽  
S Roberts ◽  
B Viani ◽  
G Pawloski ◽  
T Rose
Keyword(s):  
Secondary Mineral ◽  
Mineral Precipitation ◽  
Glass Dissolution ◽  
Melt Glass
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