Hydrogeomorphology
eisa jokar sarhangi; ghasem lorestani; vahid falah
Abstract
The studied area on the Haraz Road from Poldakhter to Vana is prone to avalanches due to its cold mountain climate. The purpose of this research is to determine the most important factors affecting the occurrence of avalanches and its risk zoning using LNRF and Shannon Entropy models. For this purpose, ...
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The studied area on the Haraz Road from Poldakhter to Vana is prone to avalanches due to its cold mountain climate. The purpose of this research is to determine the most important factors affecting the occurrence of avalanches and its risk zoning using LNRF and Shannon Entropy models. For this purpose, the criteria of snow cover, elevation, slope, aspect, slope curvature, landuse and distance from the road have been used. The results of determining the most important factors affecting the occurrence of avalanches in the studied area using Shannon's Entropy model showed that the aspect, landuse, distance from the road and snow cover with weights of 0.541, 0.143, 0.129 and 0.083 respectively are more important. Avalanche risk zoning maps show that the highest avalanche risk is due to the location of these areas at an altitude of 2100-2700 meters and a slope of 30-60 degrees with the direction of the northeastern and northern slopes. Evaluation of avalanche risk zoning maps using the empirical probability index (P) indicates the appropriateness of Shannon entropy and LNRF models in the region, but the application of Shannon entropy has led to an increase in map accuracy up to 97%.
Reza esmaili; Maryam Ghorayashvandi; Esa Jokar Sarhangi
Volume 5, Issue 17 , March 2019, , Pages 163-183
Abstract
Extended Abstract
Introduction
Flood is one of the most important hazards in the alluvial fans and its analysis is associated with many complications. The term alluvial fan flooding refers to only a specific type of flood hazards that occurs only on alluvial fans (NRC, 1996). These floods in alluvial ...
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Extended Abstract
Introduction
Flood is one of the most important hazards in the alluvial fans and its analysis is associated with many complications. The term alluvial fan flooding refers to only a specific type of flood hazards that occurs only on alluvial fans (NRC, 1996). These floods in alluvial fans are characterized as high flow velocity, different flow paths, very active erosion, transport, and deposition processes. Many of the rural and urban areas of Iran which are located in areas of alluvial fans are potentially at risk of flood. Therefore, the identification of high risk areas of flood at different scales can be useful in managing them. This research was conducted with the aims of estimating the flash flooding in the northern alluvial fan of the city of Izeh, identifying potentially hazardous areas in terms of flooding, and prioritizing them for management purposes. The study area with an area of 75 km2 is located in the north of the city of Izeh and the Lake Miangaran. The mean elevation is 1470 m. According to the Izeh meteorological station, the average rainfall in the region is 637 mm and the average annual temperature is 23 ° C.
Methodology
The boundaries of the watersheds and alluvial fans were separated and mapped using Google Earth Images of 2016. The potential of flood hazards was studied in three main steps: (1) Identifying active and passive zones of alluvial fans; the geomorphic indices including intersect point of alluvial fan, braided drainage pattern, and alluvial fan topography profile were used to identify the active and passive zones of alluvial fans. (2) The estimation of runoff and discharge with SCS method; the Ghahreman and Abkhezr method (2004) was used to calculate the amount of rainfall during different return periods. The information layers of the soil, land use, and vegetation cover were prepared from maps of the Natural Resources Administration of Khuzestan province. By combining the information layers, the curve number (CN) values for different basins and weighted average were calculated. Using the data such as catchment area, rainfall and its duration, number of the curve, length of stream and its slope, peak of flood discharge and time to peak were calculated. (3) Ranking of the risk areas by TOPSIS method; in the TOPSIS method, the n×m matrix is evaluated for a decision that has m option and n criterion. The basis of this technique is based on the notion that a selective choice should have the least distance with the positive ideal solution (best possible) and the greatest distance with the negative ideal solution (the worst possible condition).
Result
In the study area, twelve catchment- alluvial fan systems were identified. The active areas of the alluvial fans were 5 to 100% of their total areas. Based on soil characteristics and surface coverage, the average relative weight of CN varied from 78 to 90. The rainfall was calculated at 30, 60, 120, 180, and 360 minutes at the return periods of 2, 5, 10, 20, 50, and 100 years. Due to the small size of the basins and the short duration of concentration, the rainfall of 120 minutes with a return period of 10 years, which was 36.77 mm, was considered as the peak estimation criterion. To assess the ranking areas in the TOPSIS method, four criterion including flood peak due to precipitation of 120 minutes with a 10-year return period, time to peak of discharge, active alluvial fan area, and area of villages located in active alluvial fan were used. Twelve studied alluvial fans also appeared as options in the matrix. The results of the flood hazards ranking in the alluvial fans of the study area showed that fans of 2 and 5 were the villages of Perchestan Gurii with a population of 1168 people and the village of Pershestan Ali Hossein Mola with a population of 317 which had respectively had proximity coefficients of 1 and 0.4481 in rankings 1 and 2.
Discussion and conclusion
Within the studied area, the active areas of the alluvial fans are considered to be a major contributor to the flood hazard ranking so that the variables of the alluvial fans area and the area of villages based on them account for 77% of the weight of the ranking. Hence, the determination of the active regions of the alluvial fans can be used on a regional scale using Google Earth satellite 3D images. Using multi-criteria decision-making methods such as TOPSIS can rank the flood hazards in the alluvial fans of north Izeh with regard to the influential variables. This regional-level ranking can show areas at risk and, if necessary, detailed geomorphological studies and field studies will be needed.
Issa jokar sarhangi; Reza Esmaeali; Sedigeh Baba Alipour
Volume 5, Issue 14 , June 2018, , Pages 135-156
Abstract
Introduction
Drainage density is an important hydrogeomorphologic indicator in determining activity quality of processes of overland run-off, flood intensity, soil erosion and sedimentation load in the basin. Drainage density was defined as the ratio of the total length of streams in a watershed over ...
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Introduction
Drainage density is an important hydrogeomorphologic indicator in determining activity quality of processes of overland run-off, flood intensity, soil erosion and sedimentation load in the basin. Drainage density was defined as the ratio of the total length of streams in a watershed over its contributing area. It describes the degree of drainage network development and was recognized by many authors to be significantly effective on the formation of flood flows. Drainage density is higher in arid areas with sparse vegetation cover. The higher the drainage density, the lower the infiltration and the faster the movement of the surface flow. The structure of watershed topography depends to a large extent on the interaction between slope and channel processes. The applicability of these relatively simple summaries, however, needs to be examined carefully. It is still uncertain how the development of drainage systems with time affects the relation of drainage density with lithology, slope, aspect and elevation. The Behrestagh watershed is a sub-basin of Haraz River basin where in varied geological and topographic conditions and the many overland flow cause soil erosion and destruction of pastures and gardens of the area. This study examines the relationship of drainage density with Geology and topography factors for Behrestagh watershed.
Materials & Methods
The Behrestagh watershed lies between the latitudes of 35° 56΄ N to 35° 59΄ N and longitudes of 52° 16΄ E to 52° 22΄ E. The main stream in the area is Haraz River. Topographic elevations in the study area vary between 1172 to 3548 m. Here, in order to examine drainage density in the studied area, map of the watershed’s streams was prepared first using GIS and Digital Elevation Model (DEM) of that area. Then, effective Geology and topographical properties including lithology, elevation, slope and aspect was considered and classified in ArcGIS environment and finally were overlaid with the streams as a dependent variable. Accordingly, sum of streams length per unit of each factor was calculated and drainage density was obtained. Data were analyzed in SPSS 20. Moreover, collected data were described using descriptive statistics (tables, charts, abundance distribution, mean and standard deviation). Data analysis was performed using one-way ANOVA to obtain differences with other studied variables.
Discussion of Results
In this study, data analysis was performed using one-way ANOVA to obtain differences with studied variables. Results of the statistical test indicated that the relationship of lithology and slope with drainage density in the considered area was significant at .95 and .99 level of confidence, respectively. The relationship of drainage density with elevation and aspect was not significant, as well. The results showed that the most drainage density of the area was observed in elevation lower than 1400 meters (average density of 8.24). Also, the cretaceous melaphyre formation (km) with average density of 8.79 and the slope class of 20 -30 percent showed an average density of 10.7 and the western aspect (domain direction) indicated an average of 5.57.
Conclusions
To determine the geology and topography factors influencing drainage density, data layers of lithology, slope, aspect and elevation were analyzed through overlaying the dispersion map of the watershed’s streams. The results showed that cretaceous melaphyre formation, elevation below 1400 meters, slope of 20-30 percent and the west aspect are sensitive to streams. Also, results indicated a significant relationship between lithology and slope with drainage density in the considered area and slope was found to be the most important topography factor affecting drainage density. Therefore can used from these variables to assess erosion intensity and its control.