Modeling the Formation of Fluoride Nitrogen-Rich Hot Springs in the Water – Crystalline Rock System

Pavlov, S. Kh.; Чудненко, К. В.; Хромов, А. В.

doi:10.5800/gt-2020-11-2-0481

Cited by 3 publications

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References 19 publications

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“…При опробовании гидрогеохимического разреза чаще всего водопритоки получены в горизонтах песчаников, поэтому для исследования взят образец песчаника. В предыдущих работах автора впервые показано, что наиболее уязвимым местом современной гидрогеохимии, гео химии и геологии в целом является слабая изученность анионогенных элементов (C, Cl, F, S) как в изверженных [Pavlov et al, 2020;Pavlov, Chudnenko, 2023], так и в осадочных [Pavlov, Chudnenko, 2010;Pavlov et al, 2018] образованиях, поэтому исследуемый образец песчаника синтезирован. Петрогенные компоненты и недостающие анионогенные элементы взяты из разных образцов песчаника, представленных в работе [Pettijohn, 1981].…”

Section: исходные данные и методикаunclassified

Processes of Formation of Sodium Bicarbonate Groundwater in the Rainwater – Sandstone System

Pavlov

2023

Geodin. tektonofiz.

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In modeling, a study was made of the processes of the physical-chemical interaction between rainwater and sandstone. It was stated that as a result of the interaction, already in mineralization of water equal to 55 mg/l, there emerges a pure soda solution whose sharp oxidation properties, retaining up to 200 mg/l, change to sharp restorative when exceeding this value. At the mineralization of water equal to 30 mg/l, an intensive increase in the number of hydroxide ions in a solution makes it highly alkaline. The active removal of calcium from solution is due to the formation of not only solid phase calcite, whose share does not exceed 15 %, but largely limonite, whose content is as high as 25 %. The accumulation of high concentrations of sodium in a solution is caused by the absence of its secondary mineral formations in a wide range of the rock/water ratios. Under reservoir conditions, the solution is composed of carbonate. This solution, transferred from reservoir to surface conditions, undergoes transformation in the result of interaction with the atmosphere. A decrease in pH of the solution resulted in the acquisition of sharp oxidation properties, with the cation, sulfate, fluorine and chlorine contents remained at the level corresponding to the reservoir conditions and the cardinal changes affected the carbonate system components and silicon compounds. Hydrosilicate ion was transformed into precipitated silicon oxide. Carbonate ions were transformed into hydrocarbonate, and the additional hydrocarbonate ions were formed for the solution to preserve a state of equilibrium after the removal of the representative number of hydrosilicate ions therefrom. An amount of carbon required for their formation was extracted from the atmosphere. The solution became hydrocarbonate, with hydrosilicate ions almost disappeared therefrom. Different calculation options for model solution, which is in equilibrium with the atmosphere, correlate with the representative group of soda-type groundwater. The calculation results are confirmed by field observations over the authigenic mineral formation on a large part of the Russian territory.

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Section: исходные данные и методикаunclassified

Processes of Formation of Sodium Bicarbonate Groundwater in the Rainwater – Sandstone System

Pavlov

2023

Geodin. tektonofiz.

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Formation of Nitrogen-Rich Hot Springs in the Water–Granite and Water–Porphyrite Systems

Pavlov

Чудненко

2023

Geochem. Int.

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Structural features and formation processes of a complex hydrogeochemical section in the Baikal rift zone

Pavlov

2021

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The purpose of the work is to study the effect of organic matter on the formation of ion-salt and gas composition of nitrogen-methane and methane thermal water occurring in the sedimentary rocks of deep horizons of artesian basins. The object of research is the Tunka intermountain artesian basin of the Baikal rift zone and the Tungor gas and oil field of the Okhotsk-Sakhalin basin, in the deep horizons of which soda (inversion) low- and high-mineralized groundwater is common. The study combines the results of the traditional study of the composition of natural solutions and the quantitative research of physical and chemical interactions in the “water – rock” system conducted using the Selector software package according to the degree of the hydrogeochemical process, which was set by the value of the rock/water ratio. Chemically pure water and rocks of medium chemical composition were used in interaction. With the use of physicochemical modeling the formation of thermal water composition in sedimentary rocks depending on the interaction degree between water and rock and the amount of organic matter was unravelled. As a result, it was determined that the organic matter present in the rock has the dominant influence on the intensity of the hydrogeochemical process determining the amount of mineralization, the ratio of components, and the amount of methane, nitrogen, and carbon dioxide produced. The correspondent compositions of the model and natural solutions showed the possibility to form low- and high-mineralized sodium bicarbonate groundwater of different gas-saturation degree in the conditions of deep horizons of sedimentary basins due to the internal reserves of the “water – rock” system not involving any components from external sources.

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Modeling the Formation of Fluoride Nitrogen-Rich Hot Springs in the Water – Crystalline Rock System

Cited by 3 publications

References 19 publications

Processes of Formation of Sodium Bicarbonate Groundwater in the Rainwater – Sandstone System

Processes of Formation of Sodium Bicarbonate Groundwater in the Rainwater – Sandstone System

Formation of Nitrogen-Rich Hot Springs in the Water–Granite and Water–Porphyrite Systems

Structural features and formation processes of a complex hydrogeochemical section in the Baikal rift zone

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