Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1515  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

Evaluating the Effects of Dam Construction on the 
Morphological Changes of Downstream Meandering 

Rivers (Case Study: Karkheh River)   
 

Ali Liaghat 

Civil Engineering Department 
Engineering Faculty, Shahid 

Chamran University of Ahvaz 
Iran 

Arash Adib 
Civil Engineering Department 
Engineering Faculty, Shahid 

Chamran University of Ahvaz 
Iran 

 

Hamid Reza Gafouri 
Civil Engineering Department 
Engineering Faculty, Shahid 

Chamran University of Ahvaz   
Iran 

 

 

Abstract—The establishment of stability in rivers is dependent on 
a variety of factors, and yet the established stability can be 
interrupted at any moment or time. One factor that can strongly 
disrupt the stability of rivers is the construction of dams. For this 
study, the identification and evaluation of morphological changes 
occurring to the Karkheh River, before and after the 
construction of the Karkheh Dam, along with determining the 
degree of changes to the width and length of the downstream 
meanders of the river, have been performed with the assistance of 
satellite images and by applying the CCHE2D hydrodynamic 
model. Results show that under natural circumstances the width 
of the riverbed increases downstream parallel to the decrease in 
the slope angle of the river. The average width of the river was 
reduced from 273 meters to 60 meters after dam construction. 
This 78% decrease in river width has made available 21 hectares 
of land across the river bank per kilometer length of the river. In 
the studied area, the average thalweg migration of the river is 
approximately 340 meters, while the minimum and maximum of 
river migration measured 53 and 768 meters, respectively. 
Evaluations reveal that nearly 56% of the migrations pertain to 
the western side of the river, while over 59% of these migrations 
take place outside the previous riverbed. By average, each year, 
the lateral migration rate of the river is 34 meters in the studied 
area which signifies the relevant instability of the region.  

Keywords-erosion; dam; meander; morphology; CCHE2D 
hydrodynamic model. 

I. INTRODUCTION  
After the construction of any dam, the fluvial regime of the 

river is subjected to consequential change and its system or 
pattern of erosion may undergo metamorphosis. Dam 
construction alters the amount of sediment production, 
retention and transportation of the sediments in the system. 
This causes changes in the pattern of erosion and thus can alter 
the channel’s morphology in both short and long term periods. 
It can further change the morphological qualities of the bed and 
banks, which influence the amount of water transportation and 
the rise and fall in the elevation of the bed, ultimately resulting 
in the spread of flooded regions surrounding the river. All of 

the above can be attributed to the produced effect of 
morphological changes occurring to the river. The change in 
the direction of meanders is one of the most prominent 
problems regarding the instability of rivers. This change in the 
meander direction can seriously threaten the success of projects 
that are aimed at controlling floodwater. The threat can be 
explained by the fact that as meanders change their course and 
migrate, some installations such as levees and lateral flood-
controlling installations tend to lose their functionality [1]. In 
sections of meanders, there is a high gradient of change in the 
distribution of velocity along the length of the river, when 
considering the water velocity of the inner bend of the meander 
towards its outer bend. Due to the continuous change in the 
bend’s radius of curvature, fluvial parameters are more 
complex in meander sections than in straight river sections [2].  

In [3], authors stated that the most important feature of 
fluvial structure in meandering rivers is the inverted vortex 
direction of secondary flow cells at the peak of curvature, 
considered before and after the occurrence of flood. The 
intensity and direction of vortex for these secondary flow cells 
have a significant effect on the morphology of the bed and 
banks, besides affecting the distribution of flow velocity along 
the length and across the width of the river. In [4], 20 
meandering reaches were analyzed over a 128-km-long river 
reach located in the middle part of the Karoon River, Iran. The 
results of a paired t-test showed that river width and meander 
neck length have significantly changed during the study period 
(1989–2008), with an increase of + 3.5 m for width and a 
decrease of 274 m for length. In [5], it was suggested that the 
feedback mechanism between in-channel sedimentation and 
bank erosion may affect channel morphology. Here, the pattern 
of the bar area, bank erosion, and morphology of the gravel-bed 
Dunajec River upstream from the Czorsztyn Reservoir, 
constructed in 1997 in southern Poland were analyzed from 
aerial images (1982–2012). In [6], authors examined spatial 
variation in channel morphology and bed sediment character 
upstream and downstream of four run-of-river dams in Illinois. 
Results show that the four dams do not create major 
discontinuities in channel morphology or sediment character. 



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1516  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

Silt/clay content of bed material at the four sites is higher 
upstream of the dams than downstream, but this size fraction 
generally is a minor component by weight of the sediment 
samples collected. An applicable instance whereby satellite 
images are used for study is the assessment of geometrical 
changes that occur to the meanders over a period of time. 
Usually, as the rivers reach a flooded state, the water level rises 
and progresses more towards the banks. Eventually, after the 
flooding ensues, various sizes of patches of land alongside the 
river become immersed in water. The repetitive evaluation of 
satellite images provides a convenient means for the 
discrimination of geometric changes to the river.  

The amounts by which a dam affects the morphology of the 
downstream river, is largely dependent on the strategy of the 
dam and the features of the downstream river. Examples of 
studies in this field include the long term changes in the bed of 
the Rio Grande River as a result of establishing irrigation 
installations [7-8], geometrical, hydraulic changes in the 
downstream of the Hapcheon Dam [9], the effect of daily 
pulses of flow that originate from the dam on the Hwang River 
[10], evaluating the effect of the Englebright Dam on the 
downstream morphology [11] and evaluation of the effect of 
functionality of the Keystone Dam on the morphology of the 
Arkansas River [12]. It appears that the first research on the 
geomorphologic changes of rivers resulting from the 
construction of dams was conducted by Petts in the late 1970s 
which significantly influenced the future of relevant research in 
the field [13-14].   Dams can influence the fluvial pattern and 
the sediment load of the river. Upstream the reservoir of dams, 
the local groundwater level rises. Rivers that feed a reservoir 
deposit their load in their beds in the vicinity of the reservoir 
and as forms of delta inside the reservoir bed. Sedimentation 
reduces the slope of the riverbed and increases the elevation of 
the bed, thereby increasing the risk of flooding. In addition to 
the change in the length and width of the river channel, the 
occurrence of erosion in subordinate streams and in the 
stream’s origins can be greatly influenced by changes in the 
basal ground level of the channel [5-18]. In [19], authors 
described the geometric shape of the river as a reflection of its 
discharge, sedimentation and the hydrological conditions of the 
flow. Their research focused on the role of a unit factor in 
evaluating the geometric pattern of the river, but seldom 
considered systematically the geomorphic conditions and 
geological setting of the river, altogether, along its route.  In 
[20], authors applied the model of meander migration in the 
southern river of Virginia and compared the development and 
migration of meanders within the alluvial domains of sandy 
beds and rocky beds. The research showed that over 45% of 
regions the erosion model predicted to be eroded would 
eventually then actualize in field observations of erosion. In 
[21], authors evaluated the mechanism of cutoff formation 
along the length of big meanders by considering the 
topography of the floodplain and its floodwater dynamics. 
Their research claimed that reasons such as rapid changes in 
the capacity of river sections, which commonly result from the 
construction of dams and the sudden surge of floodwater, can 
generate meander cutoffs. In [22], authors assessed the stages 
by which morphodynamic meanders are formed. The 
mechanism of meander formation based on hydrodynamic 

forces was discussed along with realizing the patterns of 
change in the geometry of meanders. In [23-25], the corriolis 
effect on the making of meanders under laboratory conditions 
was simulated 

This research aims to evaluate how the construction of the 
Karkheh Dam affects morphological changes in the 
downstream meandering section of the Karkheh River. For this 
purpose, morphological changes of the Karkheh River before 
and after dam construction was evaluated by satellite images, 
along with determining the degree of changes to the length and 
width of river meanders downstream the Karkheh by assistance 
of the CCHE2D hydrodynamic model. In this research, 
evaluations are made regarding the effects of dam construction 
on the hydraulic features and morphological characteristics 
downstream the Karkheh River. In this method, the changes in 
hydraulic shapes of the river between two stations, namely Pay-
e-Pol and Abdolkhan (downstream the Karkheh Dam) were 
modeled by the CCHE2D model and the transition in plane and 
cross-section was considered in addition to the morphological 
changes in the river during the time span between the years 
1996 and 2011 which were determined based on making 
comparisons between the relevant satellite images. The 
Karkheh Dam is the biggest dam in Iran and in the Middle East 
which was completed for exploitation in 2002. This dam is one 
of the world’s biggest earth dams, which is located 22 
kilometers north-west of the city of Andimeshk in the 
Khuzestan province of Iran. The Karkheh River is the third 
biggest river in Iran in terms of discharge, after the Karoon and 
Dez Rivers. 

II. DISTRICT OF STUDY 
In order to simulate the fluvial pattern for the purpose of 

analyzing the hydraulics of meanders, a section of the Karkheh 
River (downstream the Karkheh Dam and the hydrometric 
station of Pay-e-Pol) was selected for this study. Figure 1 
displays the location of the Pay-e-Pol station on the Karkheh 
River, and Figure 2 shows the district selected for this study on 
the river. 

 

 
Fig. 1.  The location of the Pay-e-Pol station on the Karkheh River. 



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1517  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

  
Fig. 2.  Location of the selected domain of study for the Karkheh River.  

III. METHODS AND MATERIALS 
The stages of this research were: (i) to find the hydraulic 

processes of the flow and to determine its relevant features, 
besides simulating the transportation of sediments in the 
Karkheh River through the application of the CCHE2D 
software and the calculations of hydraulic parameters 
pertaining to the flow and the transportation of sediments; (ii) 
to compare the results obtained by simulations of the model of 
hydrodynamic sections and that of the identical spots, before 
and after the construction of the Karkheh Dam (via the 
assistance of satellite images) with the aim of determining the 
effects of dam construction on the river; (iii) to calculate the 
length of the river as it contributes to the river’s instability and 
to show the morphological condition of the river, before and 
after dam construction. Equations pertaining to flow, herein, 
concerned open flow channels which are relevant to the 
essentials of shallow waters. Therefore, the influence of fluvial 
vertical motion is not so much important in this circumstance, 
and for this reason the averaged two-dimensional equations are 
of suitable precision and functionality which address the depth 
of a river in most cases of simulating the hydraulics of the 
flow. The averaged equations used for the depths of the fluvial 
system for its turbulent flows are presented as the equations in 
the CCHE2D model [24]:  

Continuity equation of flow:  

0
)()(














y
hv

x
hu

t
Z

 

(1) 

Equations of momentum (movement): 

( )( )1 yyxx bx
cor

hhu u u z
u v g f v

t x y x h x y h
 


    

             
 

(2) 

uf
hy

h
x

h
hx

z
g

y
v

v
x
v

u
t
v

cor
byyyyx



































 )()(1  (3) 

In these momentum equations, especially in (2), the 
Reynolds stresses can be predicted with the help of the 
Boussinesq hypothesis according to the following [25]:  

x
u

vtxx 


 2
 

(4) 

















x
v

y
u

vtyxxy 
 

(5) 

y
u

vtyy 


 2
 

(6) 

 It is necessary to grid the environment for the discretization 
of partial differential equations governing the model in relation 
to water and sediments via numerical methods (Figure 3). The 
process involves gridding the selected domain via the 
CCHE2D Mesh Generator Model by algebraic and numerical 
methods. Then, the produced grids is assessed by the MDO and 
ADO functions. After calibrating and assessing the grids, it was 
observed that the environment gridded with i=30 and j=200 
displayed less error in comparison with gridding by other 
values of ‘i’ and ‘j’. Table I demonstrates the precision of 
gridding. Generally, grids are more precise when the values of 
the MDO and ADO functions are less. 

TABLE I.  CALIBRATING AND ASSESSING THE PRODUCED GRIDS. 

 

 
Fig. 3.  Type of  the produced grids of the selected domain. 

A.  Analysis of the daily discharge hydrograph of the flow in 
the model 
One of the most important factors in determining the 

mechanism of floodwater hydrograph combinations and the 
condition of a river system at times of flood is the temporal 
delay between the peak discharge of floodwaters of upstream 
and downstream districts of the river which directly affects the 
peak discharge of the overall floodwater. The peak of 
floodwater hydrograph is important in terms of hydraulic 
conductivity, regardless of the volume of floodwater 

Function 
(MDO) 

Function 
(ADO) 

( j )  
value 

( i )  
value 

No. 

8.23 9.46 200  20 1 
6.30 5.32 300 15 2 
2.40 1.12 200 30 3 



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1518  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

hydrograph, which posit the peak discharge of the hydrograph 
as the base for the engineering of river installations and 
designs. For this purpose, the relevant scale and condition of 
the river under critical situations of flooding which indicate the 
degree to which the surrounding lands of the river become 
flooded and immersed in water are factors determined by the 
peak discharge of the floodwater hydrograph. However, the 
influential factor affecting the erodibility of the riverbed and 
banks is mostly the long-term effect of discharge within a 
specified amount of time.  

In this research, the hydrograph of flow discharge 
pertaining to a time span of three consecutive years was 
obtained from the hydrometric station upstream the river, and 
its information was regarded as the input data for the model. A 
three-year time span was considered for the time preceding the 
construction of the dam, and a three-year time span was studied 
to consider the condition after dam construction. The pre-
construction period of three years was from September 1993 to 
August 1996, and the post-construction period of three years 
was from September 2008 to August 2011. This pattern of 
time-span selection has been practiced in previous research too 
[26]. Figure 4 shows the hydrograph of three consecutive years 
before and after the construction of the Karkheh Dam. 

 

 
Fig. 4.  The hydrograph of three consecutive years before and after the 

construction of the Karkheh Dam. 

Determination of Manning’s roughness coefficient can be 
done by the d50 value of materials which constitute the 
structure of riverbed and banks. The Strickler equation is also 
involved in the relevant calculations. 

6

1

50047.0 dn   
(7) 

Where n is Manning’s coefficient value, d50 is the average 
size of alluvial particles (m). The method of calibrating the 
surface level of water was applied for calibration and 
assessment of the model. To correlate the calculated amount of 
sediment discharge with the actual amount of sediment 
discharge, it was supposed that the Manning coefficient which 
was obtained from the calibration of surface water level 
remains valid for this stage too. Accordingly, it was realized 
that the calculated values matched quite suitably with the actual 
values observed in the experimental field. Table II displays the 
Manning coefficient in the model for various domains. 

B. Correlations between flow discharge and sediment 
discharge, the amount of suspended load and bed load in 
the CCHE2D model 
 The equation that best fits the optimum curve congruent 

with the data of flow discharge and sediment discharge of the 
Jelogir and Pay-e-Pol stations can be presented as in the 
following formula. The formula (8) is used for sediment data 
pertaining to the time before the dam was constructed, and 
formula (9) is used for sediment data of after when the dam 
was constructed [27, 28]. 

4027.2032.0 ws QQ   (8) 
357.20364.0 ws QQ   (9) 

 Where Qw is the flow discharge in m
3/s and Qs is the 

sediment discharge expressed in ton/day. 

TABLE II.  MANNING’S ROUGHNESS COEFFICIENT OF THE RIVER BEFORE 
AND AFTER THE CONSTRUCTION OF THE DAM. 

The transportation of materials in a river occurs in the form 
of bed load and suspended load, in either case it depends on the 
size of particles and the velocity or other qualities of the flow. 
The presence of various kinds of sediments (sand, silt and clay) 
in the alluvial system is partially due to the process of selective 
transportation wherein particles are arranged in their 
movements. This leads to the fact that the process is related to 
the selective motion of various sediment particles which have 
an incipient motion that is nearly equal to the shear stress in the 
bed, but which the particles can be extensively transported 
when a higher degree of shear stress rules. Accordingly, (10) 
and (11) can be used for the input data of bed load and 
suspended load in the CCHE2D model [27, 28]. 

7932.51102.0  BLQw  (10) 

2085.737.48  SLQw  (11) 
Where Qw is the flow discharge measured in m3/s and BL 

is the bed load and SL is the suspended load expressed in 
ton/day.  

C. Grain size gradation of bed load sediments 
The relationship between grain size of sediments and the 

hydraulic conditions of the flow was determined by the help of 
the flow discharge diagram in relation to the percentage of 
three different types of sediment particles in the bed load, 
namely gavel, sand and fine grains. The composition of 
sediment particles of the Karkheh River was 93.26% sand, 
4.63% gravel and 2.08% of fine grains (silt-clay). Figure 5 
shows the diagram of gradation for average grain size of 
sediment particles in the studied district of the Karkheh River. 
In the studied district of the river, the Karkheh River exhibits 
diverse widths along its course and sections. The river is very 
wide in some sections (having an extensive floodplain) and has 

Manning’s 
roughness 
coefficient 
  in 2011  

Manning’s 
roughness 
coefficient 
  in 1996 

Distance from 
Pay-e-Pol st. (km) 

Reach 
No. 

0.035 0.034  12.3 1 
0.039 0.039 20.1 2 
0.040  0.038 30.9 3 



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1519  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

tall banks in some other sections. Therefore, in most occasions, 
massive floodwaters may partially stream off the river’s main 
course and thus cause errors in the measurement and 
documentation of the floodwater by downstream hydrometric 
stations. But to solve this problem, a wide domain of river 
sections was selected which also included the river’s 
floodplain. Under these circumstances, the model can yield 
actual and logical results on a two-dimensional basis.   

 
Fig. 5.  The diagram of gradation for average grain size of sediment 

particles. 

IV. RESULTS AND DISCUSSION 
It is common knowledge that rivers are influenced by 

various factors and variables that cause them change in their 
dimension, direction and pattern. These changes have temporal 
and geographical dimensions and are affected by the discharge 
of flow and sediments, the features of input sediments to the 
system and grain size of the bed materials (of river bed and 
banks). Metamorphosis of rivers can be gradual and continuous 
in the long-term approach, or it can be sporadic and sudden if 
considered under certain circumstances in the short-run [29-
31]. The results of these changes in this research are as follows: 

A. Changes to the widths of the river 
By measuring the widths of the riverbed obtained by results 

of the model in different seasons through the course of the 
river, the trend of change for the widths of the riverbed can be 
achieved. Under natural conditions, the widths of the riverbed 
increases towards the downstream of the river’s course, parallel 
to the decline in the river’s slope angle along the length of the 
river. Figure 6 and Table III show that the width of the river 
has been reduced considerably because of dam construction. 
The overall domain of the studied district measured 31 
kilometers long. There were 34 sections considered along the 
district, and the summarization of results is presented in 6 
domains (Table III). The average widths of the river before 
dam construction was 273 meters, its maximum and minimum 
widths were 589 and 75 meters, respectively. The average 
widths of the river became 60 meters after dam construction, 
the maximum and minimum of widths after dam construction 
were 86 and 30 meters, respectively. Therefore, by an 
approximate reduction of 78% in the widths of the river, nearly 
21 hectares of land, per each kilometer of river length, was 
released from floodwater. This value pertains to the floodwater 
with a return period of two years. 

TABLE III.  AVERAGE WIDTHS OF THE RIVER BEFORE AND AFTER THE 
CONSTRUCTION OF THE DAM. 

Average widths of river (m)  
zone 

Distance end  
 of reach from Pay-e-Pol st. 

 (m) 
1996 
 year 

2011 
 year 

1 5138 219.4 51.4 
2 10852 423.1 60.3 
3 15085 289.1 57.4 
4 20060 191.6 61.2 
5 25111 215.9 57.3 
6 30982 291.0 71.9  

B. Changes to the plane of the river and lateral migration 
When there occurs a considerable change in the amount of 

flow discharge and sediment load in a meandering river, the 
plane of the river also undergoes considerable change as a 
consequence, over the specified amount of time. In Table IV, 
the migration of the river’s thalweg is shown in addition to its 
direction and status in comparison with the primary conditions 
of the riverbed. In the studied district, the average thalweg 
migration of the river is approximately 340 meters, and its 
maximum and minimum are 768 and 53 meters, respectively. 

TABLE IV.  THE THALWEG MIGRATION OF THE RIVER BEFORE AND AFTER THE CONSTRUCTION OF THE DAM. 

Sum thalweg migration 
input and output old riverbed (m) 

Sum thalweg migration 
with the primary conditions (m) 

Right direction Left direction 
 

Input old riverbed
 

 
Output old riverbed 

 

Average  
thalweg migration (m) 

Distance end 
of reach from Pay-e-Pol st. (m) 

zone 

2855 2283 2850 2288 68.4 5138 1 
0 5714  1633  4081 408.5 10852 2 

3004 1229 2244 1989 356.9 15085 3 
3706 1269 2366 2609 430.5 20060 4 
5051 0 2281 2770 373.0 25111 5 
3464 2407 3768 2103 369.4  30982 6 
18080 12902 15142 15840 - - SUM



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1520  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

Figure 6 shows the changes in plane and the lateral 
migration of the river in the studied domain, and Figure 7 
shows the diagram for thalweg migration of the river. Results 
show that over 51% of migrations occurred to the west side of 
the river, and over 58% of these migrations took place outside 
the old riverbed. The analysis of results shows that there is an 
average lateral migration of 34 meters occurring to the river 
each year, in the studied district, which signifies the instability 
of the region.  

 

 
Fig. 6.  The changes in plane and the lateral migration of the river in the 

studied domain. 

 
Fig. 7.  The diagram for thalweg migration of the river 

C. Changes to the longitudinal profile and the level of 
riverbed 
The slope angle along the length of the river is first 

controlled by the conditions and features of topographic and 
geological characteristics of the watershed region. The slope, 
however, would change gradually as a result of erosion and 
disintegration of materials. With increasing the slope value the 
erosion level of the river bed will be increased and visa versa 
(because of the velocity of water). This concludes to a 
condition that the slope of the river becomes the summation 
result of water flow effects and the influences of topographic 
and geological parameters (Figures 8 and 9). 

 

 
Fig. 8.  Changes to the longitudinal profile before the construction of the 

Dam. 

 
Fig. 9.  Changes to the longitudinal profile after the construction of the 

Dam. 

The equations for the longitudinal profile of the studied 
district, before and after dam construction, can be expressed as 
in (12) and (13), where El is the height of the riverbed (m), and 
D is the distance to the Pay-e-Pol station (m).  

9794.0

13.103
2

051






R

EL e
DE  (12) 

 

9589.0

34.102
2

051






R

EL e
DE  (13) 

D.  Changes to the cross-section of the water level 
To illustrate the cross-section of the water level, the results 

of the model’s performance was derived correspondingly in a 
congruent manner regarding the period preceding dam 
construction and the period after it. By comparing the cross-
section of the floodwater between the pre-construction and 
post-construction periods, it is evident that the level of water in 
the river has declined in most sections, because of dam 
construction.  Figures 10 and 11 show that in both cases of pre- 
and post-construction periods of the dam, the fluctuations in the 
river’s depths are sporadic in relation to the distance from the 
station, but generally these changes exhibit a trend of increase 
in the river’s depths by the longer distance from the station, in 
both cases of pre and post construction periods of dam 
construction. One reason for this increase in the river’s depth 
can be explained by the reduction in the river’s slope angle and 
the occurrence of sedimentation downstream the selected 
domain of the river.  

 

 
Fig. 10.  Changes to the cross-section of the water level before the 

construction of the Dam. 



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1521  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

 
Fig. 11.  Changes to the cross-section of the water level after the 

construction of the Dam. 

V. CONCLUSIONS 
Metamorphosis of rivers can be gradual and continuous in 

the long-term approach, or it can be sporadic and sudden if 
considered under certain circumstances in the short-run. Under 
natural conditions, the widths of the riverbed towards 
downstream the river’s course is increased, when the river’s 
slope angle decreases. In this case, significant changes occurred 
after the construction of a dam.  The average widths of the river 
reduced from 273 meters to 60 meters. By an approximate 
reduction of 78% in the widths of the river, nearly 21 hectares 
of land, per each kilometer of river length, was released from 
floodwater. This value pertains to the floodwater with a return 
period of two years. In the studied district, the average thalweg 
migration of the river is approximately 340 meters, and its 
maximum and minimum are 768 and 53 meters, respectively. 
Results show that over 51% of migrations occurred to the west 
side of the river, and over 58% of these migrations took place 
outside the old riverbed. There is an average lateral migration 
of 34 meters occurring to the river each year, in the studied 
district, which signifies the instability of the region. With 
respect to the assessment of the model’s results, the bed profile 
of the river has thus reached a relative degree of stability, and 
the channel’s slope angle is not significantly different when 
comparing between 1996 and 2006. Therefore, dam 
construction did not have a considerable effect on the general 
changes to the slope angle along the length of the river. The 
equation for the longitudinal profile of the studied domain of 
the river, before and after dam construction, is expressed in two 
exponential functions with coefficients of R2=0.96 and R2=0.98 
which shows the reduction of the river’s slope angle towards 
downstream the river and correlates with the Shulitz equation 
for changes in the slope angle along the river’s route. The 
fluctuations in the river’s depths are sporadic in relation to the 
distance from the station, but generally these changes exhibit a 
trend of increase in the river’s depths by the longer distance 
from the station, in both cases of pre and post construction 
periods of dam construction. Results suggest that the studied 
region of the Karkheh River is characterized by instability, in 
between the distance from the Pay-e-Pol station up to 40 km 
downstream of it. Therefore, future changes to the course of the 
river are anticipated to happen in the studied district. Results 
pertaining to the migration and movement of various sections 

of the river also confirm the strong likelihood of change that 
can occur to the river’s course in the future.  

REFERENCES 
[1] W. R. White, R. Bettes, E. Paris, “Analytical Approach to River 

Regime”, ASCE Journal of the Hydraulics Division, Vol. 108, No. 10, 
pp. 1179-1193, 1982 

[2] K. C. Patra, S. K. Kar, A. K. Bhattacharya, “Flow and Velocity 
Distribution in Meandering Compound Channels”, ASCE Journal of 
Hydraulic Engineering, Vol. 130, No. 5, pp. 398-411, 2004 

[3] D. A. Ervine, K. Babaeyan-Koopaei, R. H. J. Sellin,“Two-Dimensional 
Solution for Straight and Meandering Overbank Flows”, ASCE Journal 
of Hydraulic Engineering, Vol. 126, No. 9, pp. 653-669, 2000 

[4] S. Yousefi, H. R. Pourghasemi, J. Hooke, O. Navratil, A. Kidová, 
“Changes in morphometric meander parameters identified on the Karoon 
River, Iran, using remote sensing data”, Geomorphology, Vol. 271, No. 
1, pp. 55-64, 2016 

[5] M. Liro, “Development of sediment slug upstream from the Czorsztyn 
Reservoir (southern Poland) and its interaction with river morphology”, 
Geomorphology, Vol. 253, No. 1, pp.  225-238, 2016 

[6] S. J. Csiki, B. L. Rhoads, “Influence of four run-of-river dams on 
channel morphology and sediment characteristics in Illinois, 
USA”, Geomorphology, Vol. 206, No. 2, pp. 215-229, 2014 

[7] G. A. Richard, P. Y. Julien, “Dam Impacts On and Restoration of an 
Alluvial River Rio Grande, New Mexico”, International Journal of 
Sediment Research, Vol. 18, No. 2, pp. 89-96, 2003 

[8] G. A. Richard, P. Y. Julien, D. C. Baird, “Case Study: Modeling the 
Lateral Mobility of the Rio Grande below Cochiti Dam, New Mexico”, 
ASCE Journal of Hydraulic Engineering, Vol. 131, No. 11, pp.  931-941, 
2005 

[9] Y. H., Shin, P. Y. Julien, “Changes in hydraulic geometry of the Hwang 
River below the Hapcheon Re-regulation Dam, South Korea”, 
International Journal of River Basin Management, Vol. 8, No. 2, pp. 
139–150, 2010 

[10] Y. H. Shin, P. Y. Julien, “Effect of Flow Pulses on Degradation 
Downstream of Hapcheon Dam, South Korea”, ASCE Journal of 
Hydraulic Engineering, Vol. 137, No. 1, pp. 100-111, 2011 

[11] N. B. Dam, Yuba River Development Project FERC Project No. 2246, 
2011 

[12] C. A. Lott, R. L. Wiley, R. A. Fischer, P. D. Hartifield, J. M. Scott, 
“Interior Least Tern (Sternula antillarum) breeding distribution and 
ecology: implications for population-level studies and the evaluation of 
alternative management strategies on large, regulated rivers”, Ecology 
and Evolution, Vol. 3, No. 10, pp. 3613-3627, 2013 

[13] S. A. Brandt, “Classification of geomorphological effects downstream of 
dams”, Catena, Vol. 40, No. 4, pp. 375-401, 2000 

[14] J. C. Stevaux, D. P. Martins, M. Meurer, “Changes in a large regulated 
tropical river: The Paraná River downstream from the Porto Primavera 
Dam, Brazil”, Geomorphology, Vol. 113, No. 4, pp.  230-238, 2009 

[15] I. Overeem, A. J. Kettner, J. P. M. Syvitski, “Impacts of humans on river 
fluxes and morphology”, Treatise of Geomorphology, Vol. 9, No. 8, pp. 
828-842, 2013 

[16] G. E. Grant, J. C. Schmidt, S. L. Lewis, “A geological framework for 
interpreting downstream effects of dams on rivers”, in A Peculiar River,  
Water Science and Application Vol. 7, , Vol. 7, No. 8, pp. 203-219, 2003 

[17] N. Surian, M. Rinaldi, “Morphological response to river engineering and 
management in alluvial channels in Italy”,Geomorphology, Vol. 50, No. 
4, pp. 307-326, 2003 

[18] N. C. Nelson, S. O. Erwin, J. C. Schmidt, “Spatial and temporal patterns 
in channel change on the Snake River downstream from Jackson Lake 
dam, Wyoming”, Geomorphology, Vol. 200, No. 5, pp. 132-142, 2013 

[19] A. Zámolyi, B. Szĕkely, E. Draganits, G. Timár, “Neotectonic control on 
river sinuosity at the western margin of the Little Hungarian Plain”, 
Geomorphology, Vol. 122, No. 4, pp. 231-243, 2010 

[20] P. Narinesingh, J. E. Pizzuto, Applying a Model of Curvature-Driven 
Bend Migration Developed for Alluvial Rivers to a Gravel-Bedded 



Engineering, Technology & Applied Science Research Vol. 7, No. 2, 2017, 1515-1522 1522  
  

www.etasr.com Liaghat  et al.: Evaluating the Effects of Dam Construction on the Morphological Changes of… 
 

River With Reaches of Exposed Bedrock, AGU Fall Meeting Abstracts, 
2009 

[21] J. A. Constantine, S. R. McLean, T. Dunne, “A mechanism of chute 
cutoff along large meandering rivers with uniform floodplain 
topography”, Geological Society of America Bulletin, Vol. 122, No. 6, 
pp. 855-869, 2010 

[22] I. Güneralp, R. A. Marston, “Process–form linkages in meander 
morphodynamics: Bridging theoretical modeling and real world 
complexity”, Progress in Physical Geography, Vol. 36, No. 6, pp. 718-
746, 2012 

[23] M. Kurowski, “Procedural generation of meandering rivers inspired by 
erosion”, The 20th International Conference in Central Europe on 
Computer Graphics, Visualization and Computer Vision, 2012 Jun 26. 

[24] Y. Jia, S. S. Y. Wang, CCHE2D: Two-dimensional hydrodynamic and 
sediment transport model for unsteady open channel flows over loose 
bed, National Center for Computational Hydroscience and Engineering, 
Technical Report No. NCCHE-TR-2001-1, 2001. 

[25] J. Guo, P. Y. Julien, “Shear stress in smooth rectangular open-channel 
flows”, ASCE Journal of Hydraulic Engineering, Vol. 131, No. 1, pp. 
30-37, 2005 

[26] H. Avila, G. Vargas, R. Daza, “Susceptibility Analysis of River Bank 
Erosion Based on Exposure to Shear Stress and Velocity Combined with 

Hydrologic and Geomorphologic Variables”, ASCE World 
Environmental and Water Resources Congress, 2014 

[27] M. Shafai Bajestan, H. Hassanzadeh, N. M. Esfahani, Investigation of 
sedimentology and estimation of yearly sediment yeild in karkheh river, 
Khuzestan Water & Power Authority (KWPA), Technical Report, 2010 

[28] M. Ghomeshi, Result of Sedimentation types analysis (case study: 
kharkhe river, Khuzestan Water & Power Authority (KWPA), Technical 
Report, 2005 

[29] L. B. A. Michalik, T. Tekielak, “The relationship between bank erosion, 
local aggradation and sediment transport in a small Carpathian stream”, 
Geomorphology, Vol. 191, No. 2, pp. 51-63, 2013 

[30] S. Bandyopadhyay, K. Ghosh, S. K. De, “A proposed method of bank 
erosion vulnerability zonation and its application on the River Haora, 
Tripura, India”, Geomorphology, Vol. 224, No. 2, pp. 111-121, 2014 

[31] J. L. Grimaud, D. Chardon, V. Metelka, A. Beauvais, O. Bamba, 
“Neogene cratonic erosion fluxes and landform evolution processes from 
regional regolith mapping (Burkina Faso, West Africa)”, 
Geomorphology, Vol. 241, No. 3, pp. 315-330, 2015