The Relationship Between Quantitative and Qualitative Networks of Groundwater with the Characteristics of Alluvial fan in The Southern Hillside of Alborz center (Karaj to Takestan)

Document Type : Research Article

Authors

1 PhD student in Geomorphology, Department of Physical Geography, Faculty of Earth Sciences, Tehran Shahid Beheshti University, Tehran,Iran.

2 Professor in Geomorphology Department of Physical Geography, Faculty of Earth Sciences, Tehran, Shahid Beheshti University, Tehran,Iran.

3 Assistant Professor in Geomorphology, Department of Physical Geography, Faculty of Earth Sciences, Tehran, Shahid Beheshti University, Tehran,Iran.

10.22067/geoeh.2024.88423.1493

Abstract

Extended Abstract
Introduction
Groundwater is considered one of the most important indicators of environmental development, and land planners pay great attention to identifying the quantitative and qualitative status of these resources. In general, the sustainable management of groundwater resources during crises can reduce the effects of drought and water shortages. This issue is particularly significant in the central plains of Iran, where water scarcity and low rainfall are prevalent. Therefore, to manage these resources effectively, it is crucial to identify the factors that influence them. In recent years, increased attention has been paid to landforms and environmental indicators as parameters affecting the permeability and variability of groundwater. Over the past decade, there has been a notable increase in studies and articles in this field.
Among the key landforms in the geomorphology of arid and semi-arid regions of Iran are alluvial fans. Due to their unique structure, these fans provide an ideal environment for groundwater storage. This research focuses on the southern slopes of the central Alborz mountains to develop a model based on geomorphic parameters for assessing the quantitative and qualitative potential of groundwater. The findings of this study present innovative approaches to utilizing landforms in identifying areas with suitable groundwater potential.
Material and Methods
The alluvial fans located in the southern slopes of the central Alborz hills cover a significant part of the western plains of Tehran Province, as well as the southern plains of Alborz and Qazvin provinces. The total area of this region is 7,450 square kilometers, and it is part of the sub-basins of the Salt Lake system.
In this research, the morphometric characteristics of 23 alluvial fans in the southern plains of central Alborz were analyzed using correlational research and ex-post facto methods. With a practical approach, the boundaries of the alluvial fans were delineated using satellite images and topographic maps. Eleven morphometric parameters, including sweep angle, area, volume, concavity, slope, apex and base height, length, base length, radius, and height difference of the alluvial fans, were extracted.
Additionally, the relationships between water table depth, well discharge, and electrical conductivity (EC) of groundwater with morphometric parameters were evaluated using statistical analysis of 587 water wells.
 
Results and Discussion
The results showed that changes in discharge, EC, and water table depth were influenced by the morphometry of the alluvial fans, with contributions of 63%, 27%, and 54%, respectively. Furthermore, the results revealed that among the 11 morphometric parameters, increases in the average values of four parameters—area, cone length, base length, and radius of the alluvial fan—led to higher groundwater extraction potential. Conversely, decreases in apex height, sweep angle, and base height corresponded to increases in flow rates.
The findings indicated that in alluvial fans where the apex and base elevations are higher than others, the water table is lower relative to ground level due to increased sedimentation and sediment thickness. Moreover, the depth of the water table increases with the enlargement of the area, length, base length, and radius of the alluvial fans. Alluvial fans with large, circular, fan-shaped structures exhibited higher levels of groundwater stagnation.
 
Conclusion
Reducing concavity or sediment diameter on the surface of alluvial fans can effectively decrease soil refinement during water infiltration. This study highlights that examining geomorphic landforms prior to implementing water resource management plans can The analysis of groundwater electrical conductivity (EC) demonstrated that EC values increased in alluvial fans with high sediment volume and low concavity.significantly reduce errors in selecting locations for aquifer recharge or groundwater well excavation.
This research, through its innovative approach and robust statistical analysis, has introduced a new model to evaluate the role of alluvial fans in the quantitative and qualitative changes in groundwater. The findings offer an efficient and effective framework for identifying groundwater table potentials, providing valuable insights for sustainable water resource management.

Keywords

Main Subjects

References

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Journal of Geography and Environmental Hazards
Volume 13, Issue 4 - Serial Number 52
December 2024
Pages 130-158

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History

  • Receive Date: 09 June 2024
  • Revise Date: 01 September 2024
  • Accept Date: 03 October 2024

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