THE INFLUENCE OF HYDRODYNAMIC ASPECTS OF GROUNDWATER LEVEL RISE ON URBAN WATERLOGGING
Keywords:
groundwater, urban waterlogging, hydrodynamics, hydrogeochemistry, urban ecological environment, water migration, salt migration, geochemical classification, sulfate corrosion, environmental monitoring, land reclamation, hydrogeology.Abstract
This article presents a systematic analysis of the hydrodynamic and hydrogeochemical aspects
of groundwater level rise contributing to the waterlogging of urban areas. The study applies a differentiation
approach based on the hierarchical organization of systems and characteristic zones, examining the influence
of salt and water migration on the urban ecological environment. The degree of certainty of hydrogeological
structures and their principal causal factors are investigated, while the transformation processes of groundwater
under urban conditions are comprehensively described. Systemic factors determining the susceptibility of
territories to waterlogging, as well as specific taxonomic units and criteria for geochemical classification, are
also developed.
The article establishes a scientific basis for managing hydrodynamic processes aimed at mitigating
waterlogging problems in residential areas. The research findings are of considerable importance for improving
urban planning practices and environmental monitoring systems. During the study, the dynamics of salt and
water migration were analyzed using the equation proposed by S.F. Averyanov, enabling the determination of
groundwater mineralization levels and corrosive properties. Through the application of differentiation methods
across characteristic zones and the identification of systemic susceptibility factors, the study develops a
geochemical classification and taxonomic criteria for modified groundwater. These findings provide a scientific
foundation for planning land reclamation measures aimed at improving the urban ecological environment and
protecting building foundations from sulfate corrosion.
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