akta4


Journal of Env. Geogr. Vol. I. No. 1-2. pp. 31-39 

FLOODPLAIN AGGRADATION CAUSED BY THE HIGH MAGNITUDE FLOOD OF 2006 IN 
THE LOWER TISZA REGION, HUNGARY 

Sándor, A.1 – Kiss, T.1 

1Department of Physical Geography and Geoinformatics, University of Szeged, H-6722 Szeged, Egyetem u. 2-6, Hungary 
andrea.sandor@gmail.com,  kisstimi@earth.geo.u-szeged.hu 

Abstract 

The area of floodplains in the Carpathian Basin was dramatically 
reduced as a result of river regulation works in the 19th century. There-
fore, the accumulation processes were limited to the narrower flood-
plains. The aims of the presented study are to determine the rate of 
accumulation caused by a single flood event on the active, narrow 
floodplain of the Lower Tisza and to evaluate the relations between the 
aggradation, flow velocity during the peak of the flood and the canopy.  
The uncultivated lands in the study area cause increased roughness 
which decreased the velocity of the flood, influencing the rate of 
aggradation. The highest flow velocity was measured on points where 
the flood entered to the floodplain and at the foot of the levee. These 
points were characterised by thick (over 50 mm) and coarse sandy 
sediment. In the inner parts of the floodplain flood conductivity zones 
were formed, where the vegetational roughness was small. In the inner 
parts of the floodplain the rate of aggradation was influenced by the 
geomorphology and the vegetation density of the area. 

Key words: Lower Tisza, floodplain, accumulation, flow 
velocity, roughness 

INTRODUCTION 

The rate of floodplain aggradation is important from 
the point of view of increasing flood hazard and the 
dispersion of pollutants during flood events. Therefore, 

the rate of accumulation caused by single floods is stud-
ied along several temperate zone rivers (Gomez B. et al. 
1997, Asselmann N. E. M. – Middelkoop H. 1998, Nagy 
B. 2002, Steiger J. – Gurnell A. M. 2002, Benedetti M. 
M. 2003, Oroszi V. et al. 2006). The accumulation is 
affected by several different factors which differ in time 
and space. The most widely cited and probably the most 
important factor is the geomorphology of the floodplain 
(Cazanacli D. – Smith N. D. 1998, Baborowski M. et al. 
2007), the roughness of the inundated area (Rátky I. – 
Farkas P. 2003, Werner M. F. G. et al. 2005) and its land 
use (Knox J. C. 2006). Most studies analyse the pattern 
of the sediment deposited by a single flood event (Wall-
ing D. E. – He Q. 1998, Gábris Gy. et al. 2002) and its 
grain-size distribution (Hughes D. A. – Lewin J. 1982, 
Zhao Y. et al. 1999), or the connection between the flow 
velocity and the deposited sediment (Wyzga B. 1999).  

The flood in 2006 was the highest recorded flood 
since 1842, when the gauge station network was estab-
lished along the River Tisza (at the study area – 
Mindszent – the former record, 1000 cm in 2000 was 
replaced by 1062 cm on April 21 2006). In this area 
recent accumulation processes were studied after the 
1998-1999, 2000 and 2001 floods (Kiss T. – Fejes A. 

 
Fig. 1 The study area and the location of cross-sections, along them the depth of the fresh sediment, water velocity and the 

density of vegetation were measured 



32 A. Sándor – T. Kiss  JOEG I/1-2 
 

2000, Kiss T. et al. 2002). The aims of the present study 
are (1) to determine the accumulation rate caused by an 
extremely high flood and (2) to study the relationships 
between aggradation, flow velocity during peak flow and 
vegetation structure. 

STUDY AREA AND THE 2006 FLOOD 

The studied floodplain section is located in the 
Lower Tisza Region (Fig. 1), 6.5 km along the river 
(216.9-210.6 fkm), west of Mindszent. Here the River 
Tisza has three well-developed meanders; the lowermost 
is the sharpest. The artificial levees were built in 1890-
1895, creating a narrow floodplain with quite irregular 
width, as the distance of the levee from the right bank 
varies between 35 and 560 m, while on the left side it is 
110-1100 m respectively. The floodplain is flat, the dif-
ference in altitude slightly exceeds 2 m. The lowest fea-
tures on the floodplain are swales and artificial sandpits 
and channels, and the higher ones are point bars and 
natural levees.  

In the year 2006 two floods were recorded between 
April 10 and July 5 (Fig. 2). The first in April and May 
was 70-day-long, reaching a new record flood-level 
(1062 cm), and then a smaller and shorter flood-wave 
proceeded in June. The first was caused by the rapid 
snowmelt in the catchment and by the back-drainage of 
the Danube, while the second was due to high precipita-
tion. Altogether the floodplain was covered by water for 
102 days. 

 
Fig. 2 Recorded water level at the Mindszent fluvio-meter in 

2006 (data: www.vizadat.hu).  
The arrow indicates flow velocity measure date 

METHODS 

Flow velocity measurements were carried out in or-
der to determine the relation between flood flow and 
aggradation rate, and to reveal the role of vegetation in 
affecting flood flow. The number of flow velocity meas-
urements were limited, as it had to be made within one 
day (April 30, 2006 at 1018 cm, just after the peak of the 
flood), because of the rapid falling. A calibrated Russian 

flow velocity meter (GR-21) was used from a motor 
boat, which was anchored. The measurements were 
made just on the left bank, along 12 cross-sections at 87 
points. The exact location of each measurement-point 
was determined by Garmin GPS. Only at one point we 
measured the flow velocity at different depths to reveal 
the role of bushes in reducing flow. However, at each 
point we made only one measurement at the depth of 90 
cm, partly because we wanted to make as many meas-
urements as possible all over the floodplain, and partly 
because we could not hold it vertically in greater depth. 
The depth of the water column over the floodplain was 
4.7 m in average (max. 5.2 m, min. 2.9 m). 

At late summer the depth of the fresh sediment was 
measured along the same cross-sections as of the flow 
velocity measurements and along new cross-sections at 
both sides of the river (on ca. 500 points along 31 cross-
sections). The leaf-layer of last autumn and the artificial 
surfaces created a reference level, therefore the depth of 
fresh sediment could be precisely measured. The grain-
size distribution was determined by pipetten method and 
wet sieving. 

Simultaneously with sediment measurements the 
arboreous vegetation of each point was described, 
namely species distribution and vegetation density. 
(Vegetation density was defined in different ways; their 
description can be seen below). In 3.0 x 3.0 m quadrates 
all the bushes and trees were counted and their periphery 
was measured at 1.0 m height. This mapping and the 
aerial photo, made in 2000, were used to create the can-
opy map of the area, using ArcView3.2. software. Based 
on the aerial photo the vegetation patches were identi-
fied, and based on the field measurements their average 
vegetation density was calculated. 

Trees and bushes cover the largest proportion of the 
area (74.1%), and they play the most important role in 
increasing the roughness; therefore, these areas were 
classified from the point of view of flood conductivity. 
At first the quadrates were classified (Table 1) based on 
indices reflecting the number and size of trees. The den-
sity index was defined as the number of trees and bushes 
in the quadrate; the periphery index is the total sum of 
the periphery of the timber. In the final classification 
(Table 2) the above-mentioned two indices were 
summed (canopy index), but the density index was ac-
centuated as according to our field observations it influ-
ences the flow velocity more.  

In the quadrates belonging to the "sparse vegeta-
tion" class some old trees or in case of young planted 
forest no more than 10 trees grow, the underwood is 
sparse or missing. In the "dense vegetation" class at least 
15 trees grow in a quadrate. These forests are undis-
turbed natural forests, planted poplar stands with sparse 
underwood. The "medium dense vegetation" category 



JOEG I/1-2 Floodplain aggradation caused by the high magnitude flood of 2006 in the Lower Tisza Region, Hungary 33 
 

includes disturbed natural forests, poplar stands (at least 
45 tree/bush per quadrate) and lands where Amorpha 
bushes appear. The "very dense vegetation" means all 
those areas (forests, former orchards and plough fields) 
which are overgrown by dense Amorpha bushes. Most of 
the study area (67%) belongs to the category of medium 
and very dense vegetation classes. 

Table 1 Classes based on density and periphery indices 

Density index Number of timber 

10 >45 

9 41-45 

8 36-40 

7 31-35 

6 26-30 

5 21-25 

4 16-20 

3 11-15 

2 6-10 

1 1-5 

 

Periphery index Sum of periphery (cm) 

5 >160 

4 120-160 

3 80-120 

2 40-80 

1 <40 

Table 2 Vegetation classes based on the canopy index 

Vegetation 
class 

Density 
index 

Total 
periphery 

index 

Canopy 
index 

Number 
of quad-

rates 

Sparse  1-2 1-2 2-4 13 

Dense  3-4 1-3 4-6 6 

Medium 
dense  

3-7 1-4 6-9 22 

Very dense 6-10 1-54 10-15 21 
 

Vegetation classes were then converted into rough-
ness categories (Table 3) in order to determinate the 
mean vegetational roughness of the floodplain, following 
the roughness categories of Manning (Chow V. T. 1959). 
However, these categories might vary by the level of the 
flood: during smaller floods the trunk of trees and bushes 
submerged increasing the roughness, but as the water-
depth increases, free flood flow might occur over the 
dense bushes (Chow V. T. 1959, Németh E. 1959). Be-
sides, the roughness changes within the same forest, as it 
is smaller on roads but greater on the boundaries. 

Table 3 Roughness categories (after Chow V. T. 1959) 

Category Type of vegetation/land use 
Mean 

roughness 
(n) 

1 River channel 0.03 

2 Short grass, dirty road 0.03 

3 Cultivated plough-field 0.035 

4 
Cultivated orchard, uncultivated 
plough-field, clearings 

0.05 

5 
Inundated shallow depressions 
(sand-pit, scour channel etc.) 

0.05 

6 Uncultivated orchard 0.07 

7 Forest with sparse underwood 0.12 

8 
Dense forest dense Amorpha 
bushes  

0.2 

RESULTS 

Vegetation of the study area in 2006  

The largest proportion of the study area (74.1%) is 
covered by arbours: most of the forests (67.4%) have 
natural underwood and only 5.7% has a cleared ground 
without underwood. However, the land use of the flood-
plain differs at the two banks of the river: the right side 
is almost totally covered by forest (willow, poplar and 
the invasive Amorpha fruticosa); but the left side is close 
to the town, therefore, cultivated areas (orchards 10% 
and plough fields 10.8%) also appear. However, after the 
great flood in 2006 many of the orchards and plough 
fields remained uncultivated (4.7% and 8.8%, respec-
tively). On fields, which remained fallow land for few 
years (4.9%) invasive species (Amorpha fruticosa, Echi-
nocystis lobata) create almost impenetrable stands.  

The roughness (n) of the study area is between 0.03 
and 0.2, the mean roughness is 0.13, which is considera-
bly high, falling into the category of "forest with sparse 
underwood". Over half of the territory (60%) is covered 
by the two highest roughness categories (Fig. 3), and 
less than 10 % is under 0.035.  

Flow velocity changes at the floodplain 

Due to the limited number of velocity measure-
ments, no velocity distribution map of the floodplain was 
made. The cross-sections will be presented, which are 
grouped based on the velocity distribution along them. 
Some has the highest flow velocity in the middle of the 
cross-section, while others have higher flow velocities at 
their ends.  

The first group contains such cross-sections (Ml-2, 
Ml-5, M l-8 and M l-13), where high flow velocity was 



34 A. Sándor – T. Kiss  JOEG I/1-2 
 

measured at the middle of the cross-section. Their length 
varies between 200 and 1080 m (Table 4). The most 
characteristic is the M l-13 cross-section (Fig. 4), which 
is located in the inner bend of the lowermost meander. 
At the foot of the levee, covered by grass (n=0.03), high 
flow velocity (0.6 m/s) was measured, but in the planted 
poplar stand with dense underwood (n=0.2) the flow 
velocity reduced remarkably (0.15 m/s). In the inner part 
of the cross-section higher velocities were measured 
over a road (0.32 m/s) and on the boundary between the 
bushes and the plough field (0.46 m/s). Over the im-
merged dense bushes no movement was detectable under 
the depth of 90 cm (at the level and below the top of the 
bushes), therefore, we made more measurements at this 
point to find out the vertical velocity distribution (Fig. 
5). Flow velocity was above 0 m/s only over the im-
merged bushes: the highest velocity was measured at the 
surface (at 10 cm 0.13 m/s), then it decreased to 0 m/s at 
the depth of 70 cm. This information suggests that in 
very dense Amorpha stands (n=0.2) the roughness is so 
high that it prevents the waterflow and thus, it is only 
possible over the bushes. At the bank (on the point-bar) 
0.21 m/s flow velocity was measured. The mean flow 
velocity of the cross-section was 0.18 m/s. The phe-
nomenon, that relatively high flow velocity is typical in 
the middle of the cross-section, is in connection with 
flood conductivity routes. In these cases longitudinal 
patches with low vegetation roughness (road or forest 
clearings) or deeper swales between two former point-
bars enabled faster flow (Table 5).  

 

 
Fig. 3 Vegetation patches classified by their roughness (n) 

Table 4 Data of cross-sections with high flow velocity in the 
middle 

Flow velocity 
(m/s) Cross-

section 
Length 

(m) 

Number of 
measure-

ment 
points min. mean max. 

Roughness 
(n) 

M l-2 200 6 0 0.17 0.37 n=0.03-0.2 

M l-5 650 11 0 0.15 0.62 n=0.03-0.2 

M l-8 350 5 0 0.23 0.36 n=0.03-0.2 

M l-13 1080 13 0 0.18 0.6 n=0.03-0.2 

Table 5 Characteristics of the points situated in the middle of 
cross-sections and characterised by high flow velocity 

Cross-
section 

Description of the point 
Distance 
from the 
river (m) 

Flow veloc-
ity 

(m/s) 

M l-2 
Road parallel to the 
river 

55 0.37 

M l-5 
Low-lying surface, 
swale 

305 0.37 

M l-8 
In clearings parallel to 
the river 

103 0.36 

M l-13 
Road parallel to the 
river (2 points) 

335 and 667 
0.46 and 

0.32 

 

 
Fig. 4 Flow velocity distribution of the cross-section M l-13 

(the vegetation type and the roughness are also indicated)  

The second group of cross-sections is characterised 
by low flow velocity at their middle zones (M l-3, M l-6, 
M l-7, M l-9, M l-10 and M l-11). Their length varies 
between 330 and 630 cm (Table 6). The cross-section M 
l-6 is very typical for this group (Fig 6). Its length is 550 
m, and the greatest flow velocity (0.56 m/s) was meas-
ured at the grass-covered levee (n=0.03). In the middle 
of the cross-section the roughness is higher (n=0.05-0.2), 
therefore, the flow velocity decreased to 0.12-0.2 m/s. 
Near the riverbank, in an old undisturbed gallery forest 
the flow velocity increased (0.53 m/s). The mean flow 
velocity of the cross-section is 0.22 m/s. In this cross-
section group high flow velocity was typical at the river 
bank, partly because the morphological situation of the 



JOEG I/1-2 Floodplain aggradation caused by the high magnitude flood of 2006 in the Lower Tisza Region, Hungary 35 
 

point (at inflexion and at convex bank, where the flood 
entered to the floodplain), and partly because the smaller 
roughness in forest with limited underwood or over the 
road running at the riverbank.  

 
Fig. 5 Vertical velocity distribution over dense bush, at a point 

225 m far from the channel 

One longitudinal section (length: 680 m) was also 
made in the lowest and sharpest meander, between its 
inflexion points (Fig. 7). At the upper inflexion point, 
where the flood entered to the floodplain (forest clear-
ance), the greatest flow velocity (0.55 m/s) of the section 
was measured. As the distance increased from the bank, 
the flow velocity decreased. Along the section the 
roughness was almost the same (n=0.03) as it was used 
as ploughland. However, on the edge of the ploughland 
and a forest (n=0.12-0.2) smaller flow velocity was 
measured. At the end of the section, at the riverbank 
flow velocity was again higher (0.37 m/s), though not as 
great as at the upper inflexion point. The mean flow 
velocity of this longitudinal section is 0.34 m/s, much 
higher than any of the cross-sections, showing the exis-
tence of a flood conductivity zone.  

Table 6 Data of cross-sections with low flow velocity in the 
middle 

Flow velocity 
(m/s) Cross-

section 
Lenght(

m) 

Number of 
sampling  

points 
min. mean max. 

Roughness 
(n) 

M l-3 630 9 0 0.22 0.28 n=0.03-0.2 

M l-6 550 7 0.12 0.22 0.56 n=0.03-0.2 

M l-7 415 6 0.1 0.17 0.3 n=0.03-0.2 

M l-9 360 5 0 0.15 0.27 n=0.03-0.2 

M l-10 320 6 0.07 0.27 0.4 n=0.03-0.2 

M l-11 560 8 0.5 0.3 0.68 n=0.03-0.2 

 
 
 

 
Fig. 6 Flow velocity distribution of the cross-section M l-6 

(vegetation type and roughness are also indicated) 

 
Fig. 7 Flow velocity distribution of the longitudinal section 

(vegetation type and roughness are also indicated) 

Based on the results above, it can be stated that the 
greatest flow velocity on the floodplain is typical on 
patches running parallel to the river with low vegeta-
tional roughness, i.e. at the grassy levee, at roads and in 
poplar plantations with limited underwood. However, in 
areas invaded by Amorpha bushes the flow velocity 
drastically decreases, only over the bushes could the 
flood waterflow. Geomorphology of the riverbed deter-
mines where the flood can enter the floodplain, but in 
this case again the vegetation influences its efficiency. 
Morphology of the floodplain is also important as in the 



36 A. Sándor – T. Kiss  JOEG I/1-2 
 

deeper swales, as well depending on vegetation condi-
tions, greater flow velocity is typical.  
 

Aggradation caused by the 2006 flood 

The depth of deposited sediment was the greatest 
(50-500 mm) within 10-50 m from the channel. On the 
left side of the river, where the floodplain is narrow, the 
amount of aggraded sediment exponentially decreased 
with distance from the channel (Fig. 8), in accordance 
with earlier research (Walling D. E. – He Q. 1998). 
However, the left part of the floodplain is wider, there-
fore, the pattern of deposition was different, because 
other factors (geomorphology and vegetation) also influ-
enced the aggradation. For example, we found patches 
with low aggradation rate. These areas were covered by 
very dense Amorpha bushes which acted as a barrier for 
the flowing water. Therefore, the water slowed down and 
even stopped among the bushes; thus, sedimentation 
took place on the boundary of the patch. The effect of 
floodplain geomorphology on aggradation was obvious 
where the floodplain was wide. In these cases thicker 
sediment was deposited in the deeper areas as in sand-
pits, swallows and along a scour channel. At the points 
where the flood entered into the floodplain the aggrada-
tion was also greater.  

The 31 cross-sections were grouped based on their 
length (Table 7). Group No. I contains those shorter than 
150 m, while wider sections belong to the group No. II.  

Table 7 Major characteristics of the studied cross-sections 

Thickness of the 
fresh sediment 

(mm) 

Mean 
flow 

velocity 
(m/s) 

Cross-section 
group 

Cross-
section 

Lenght 
(m) 

min. Mean max.  
M l-1 105 0.5 34.21 125 - 
Mr-3 45 0.5 1.45 6 - 
M r-4 60 0.5 22.43 135 - 
M r-5 60 0.5 10.76 70 - 
M r-6 35 0.5 49.91 130 - 

N
o

.I
. 

S
h

o
rt

er
 t

h
an

  
1

5
0 

m
 

M r-7 143 0.5 30.81 230 - 
M l-4 710 0.5 9.3 260 - 

M l-11 555 0.5 45.93 150 0.3 
M r-1 560 0.5 7.14 48 - 
M r-2 400 0.5 2.98 15 - 
M r-9 220 0.5 13.59 500 - 

M r-10 300 0.5 5.99 186 - 
M r-11 230 0.5 19.25 500 - 

N
o

.I
I/

1.
 

E
x

po
n

en
ti

al
 c

h
an

g
e 

o
f 

se
d

im
en

ta
ti

o
n

 

M r-12 353 0.5 65.15 250 - 
M l-3 625 0.5 8.11 200 0.22 
M l-5 675 0.5 5.45 120 0.15 
M l-8 310 0.5 8.77 144 0.15 
M l-9 370 0.5 13.82 280 0.15 

M l-10 330 0.5 18.04 170 0.27 
M l-12 1085 0.5 4.41 35 - 
M l-16 395 0.5 15.59 300 - 

II
./

2
a 

M r-8 200 0.5 47.91 255 - 
M l-6 550 0.5 6.16 140 0.22 

M l-14 750 0.5 7.75 80 0.09 
M r-13 250 0.5 4.71 90 - II

./
2

b
 

M r-14 347 0.5 34.44 280 - 
M l-2 200 0.5 27.94 203 0.17 
M l-7 410 0.5 5.16 162 0.17 

M l-13 1080 0.5 12.61 150 0.18 

N
o

.I
I.

 L
o

ng
er

 t
h

an
 1

5
0 

m
 

N
o

.I
I/

2.
 M

o
re

 p
ea

k
s 

o
n

 s
ed

im
en

ta
ti

o
n

 g
ra

p
h

 

II
./

2
c 

M l-15 585 0.5 8.33 20 - 
 

The No. I. cross-section group includes the shortest 
ones (6). A typical example of this group is the Mr-4 
cross-section which is only 58 m in length (Fig. 9). The 
greatest amount of sediment (135 mm) was deposited on 
the margin of the channel in a forest with very dense 
underwood. As far as 20 m from the channel the amount 
of accumulation was only 15 mm (decreased by 89%), 
and 50 m far it reduced to 3 mm. Here the aggradation 
from the channel towards the levee decreased exponen-
tially (R2=0.9182).  

Group No. II. consists of cross-sections wider than 
150 m (24). It was also divided based on the thickness 
changes of the sediment, namely whether it changed 

 
Fig. 8 Pattern of aggradation in the study area 



JOEG I/1-2 Floodplain aggradation caused by the high magnitude flood of 2006 in the Lower Tisza Region, Hungary 37 
 

exponentially (No.II/1) or it had more peaks (No.II/2). 
Typical example for the first group is the Ml-11 cross-
section starting from the upper inflexion point of the 
lowest meander (Fig. 10). Here the greatest amount (150 
mm) of sediment was deposited within 180 m zone from 
the channel, in a poplar forest with dense Amorpha 
bushes. At 190 m from the channel the accumulation 
suddenly decreased (30 mm) at the border between a 
plough field and a dense scrub. Grain size distribution 
also changed, as on the banks the sediment consisted 
95% sand, but at 190 m from the channel it was only 
67%. Towards the levee thickness of the fresh deposit 
decreased and became finer.  

 
Fig. 9 Aggradation along the cross-section Mr-4 

 

In some cross sections (No. II/2b) the maximum 
aggradation was measured at the channel and somewhere 
in the mid-zone of the cross-section. An example is the 
Mr-7 cross-section where 230 mm sediment was depos-
ited on the bank (Fig. 12), but in 10 m it decreased to 
180 mm, and in 25 m far it decreased further to 22 mm. 
From this point, increasing amount of sediment was 
measured (max. 60 mm) towards the levee.  

  

 
Fig. 10 Aggradation along the cross-section Ml-11 and the 

grain size distribution of sediment 

In case of some cross-sections (i.e. No. II/2) more 
peaks appeared on the aggradation graphs. In some of 
them (No. II/2a) the greatest accumulation was measured 
at the bank and near the levee. One of them is the Ml-3 

cross-section, where at the bank 200 mm thick sediment 
was deposited, but already at 40 m from the bank the 
sedimentation decreased to 38 mm, and at 150 m only to 
6 mm, respectively (Fig. 11). In the middle part of the 
cross-section only very thin (less than 1 mm) sediment 
was deposited on a plough field. Near the levee (490 m 
far from the river) again thicker, 3-10 mm sediment 
accumulated in the deeper lying sand-pits.  

 
Fig. 11 Aggradation along the cross-section Ml-3 

 
Fig. 12 Aggradation along the cross-section Mr-7 

 

 
Fig. 13 Aggradation along the cross-section Ml -13 and the 

grain size distribution of sediment  

Altogether four such cross-sections exist (No. II/2c) 
where three aggradation peaks were detected. For exam-
ple, in the Ml-13 cross-section the accumulation rate 
decreased exponentially (from 150 mm to 8 mm) in 200 
m from the bank (Fig. 13), and the sediment became 
finer. In the middle of the section (ca. 580-680 m from 



38 A. Sándor – T. Kiss  JOEG I/1-2 
 

the channel) the amount of sediment increased (9-15 
mm) and became coarser. The third sediment peak (3-7 
mm) was measured in the sand-pit, near the levee, 950-
1010 m far from the river. It suggests the existence of a 
flood conductivity zone; this fact, nevertheless, is also 
supported by the geomorphology (swale).  

Based on the results listed above, it could be stated 
that the primary factor influencing the aggradation on the 
floodplain is the distance from the channel (Fig. 14). The 
greatest depth of sediment is deposited in form of point-
bars and levees. From the banks the accumulation expo-
nentially decreases towards the levees. The next factor is 
the pattern of the channel, as (1) where the water enters 
to the floodplain the aggradation is much higher com-
pared to the neighbourhood, and (2) in case of the 
sharper bend the floodplain plays important role in flood 
conductivity, and therefore, in the flood conductivity 
zone more sediment was deposited.   

 
Fig. 14 Distance from the channel is plotted against the rate of 

accumulation in case of different roughness 

Geomorphology belongs to the local factors influ-
encing the rate of aggradation, as in deeper areas (e.g. 
swale, scour-channel and sand-pit) the accumulation is 
always greater. Far from the channel vegetation plays the 
most important role in the process of sedimentation. 
Here the very thick bushes prohibit the waterflow, thus 
the aggradation is smaller (less than 1 mm) than in areas 
at similar location (similar distance from the channel and 
similar geomorphological situation). Due to the above-
mentioned local factors the exponential function can be 
applied only where the floodplain is narrow (max. 150 
m).  

The grain-size distribution of the sediment changes, 
as the sediment becomes finer departing from the chan-
nel. However, in flood conductivity zones coarser mate-
rial was found in accordance with the flow velocity. The 
coarsest material is deposited in the area of natural lev-
ees and point bars.  

CONCLUSION 

The present land use of the area causes increased 
vegetational roughness (mean n=0.13), as 74% of the 

study area is covered by forest with dense underwood, 
uncultivated orchards and ploughlands. Increased rough-
ness highly influences the waterflow: the denser the 
vegetation is the slower the waterflow on the floodplain 
becomes. The highest flow velocity is typical at those 
points where the flood enters the floodplain and at the 
foot of the levee. On the floodplain, where the roughness 
is small and therefore flow velocity is high, flood con-
ductivity zones are formed running parallel with the 
river.  

The rate of aggradation is primarily determined by 
the distance from the channel. The thickest (over 50 mm) 
and coarsest (95% of sand) sediment is deposited within 
10-50 m from the channel, in the zone of point-bars and 
natural levees, independent of vegetation. The sediment 
became finer and the rate of aggradation decreased with 
the distance from the channel. In the flood conductivity 
zones, which run parallel with the channel and where the 
vegetation is sparse, thicker and coarser sediment was 
deposited. 

In the narrow floodplain sections the rate of aggra-
dation fits the exponential curve (R2=0.8-0.9) as it was 
described in previous studies. However, where the 
floodplain is wider than 150 m, the aggradation is influ-
enced by not only the distance from the channel, but also 
by the geomorphology of the area and the density of 
vegetation. 

The pattern of fresh sediment follows the channel; 
however, in the southern sharp bend the flood makes a 
"short-cut", as it was reflected not only by higher flow 
velocity but also by greater aggradation. Patches charac-
terised by small aggradation develops under very dense 
vegetation, where the flow velocity decreased to zero. It 
means that the very dense vegetation acts as a barrier 
against waterflow, therefore, sedimentary processes are 
more pronounced on their edges and much less sediment 
is deposited within.  

Comparing these results with earlier measurements 
made in the same study site along the same cross-
sections (Kiss T. – Fejes A. 2000, Kiss T. et al. 2002), 
we can state that the pattern of aggradation was very 
similar in each year. The rate of aggradation slightly 
differed, as in 2000 the mean accumulation on the flood-
plain was 20.5 mm (Kiss T. et al. 2002) and now it was 
18.9 mm.  

Acknowledgements 

The work was financially supported by the OTKA 62200 research 
grant. 

References 

Asselmann N. E. M. – Middelkoop H. 1998. Temporal vari-
ability of contemporary floodplain sedimentation in the 



JOEG I/1-2 Floodplain aggradation caused by the high magnitude flood of 2006 in the Lower Tisza Region, Hungary 39 
 

Rhine–Meuse delta, the Netherlands. Earth Surface Proc-
esses and Landforms 23: 595-609 

Baborowski M. – Büttner O. – Morgenstern P. – Krüger F. – 
Lobe I. – Rupp H. – Tümpling W. V. 2007. Spatial and tem-
poral variability of sediment deposition on artificial-lown 
traps in a floodplain of the River Elbe. Elvironmental Pollu-
tion 148: 770-778 

Benedetti M. M. 2003. Controls on overbank deposition in the 
Upper Mississippi River. Geomorphology 56: 271-290 

Cazanacli D. – Smith N. D. 1998. A study of morfology and 
texture of natural levee – Cumberland Marshes, Saskatche-
wan, Canada. Geomorphology 25: 43-55  

Chow V. T. 1959. Open Channel Hydraulics. New York: 
McGraw-Hill. 89-127 

Gábris Gy. – Telbisz T. – Nagy B. – Belardinelli E. 2002. A 
tiszai hullámtér feltöltıdésének kérdése és az üledékképzıdés 
geomorfológiai alapjai. Vízügyi Közlemények 84: 305-322 

Gomez B. – Phillips J. D. – Magilligan F. J. – James L. A. 
1997. Floodplain sedimentation and sensitivity: Summer 
1993 flood, upper Mississippi River valley. Earth Surface 
Processes and Landforms 22: 923-936 

Hughes D.A. – Lewin J. 1982. A small-scale floodplain. Sedi-
mentology 29: 891-895  

Kiss T. – Fejes A. 2000. Flood caused sedimentation on the 
foreshore of the Tiver tisza. Acta Geographica Szegediensis 
37: 51-55 

Kiss T. – Sipos Gy. – Fiala K. 2002. Recens üledékfelhal-
mozódás sebességének vizsgálata az Alsó-Tiszán. Vízügyi 
Közlemények 84/3: 456-472 

Knox J. C. 2006. Floodplain sedimentation in the Upper Mis-
sissippi Valley: Natural versus human accelerated. Geomor-
phology 79: 286-310 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Nagy B. 2002. A felsı-Tiszai árvizek kialakulásának tényezıi, 
különös tekintettel az utóbbi évek katasztrófáira, illetve azok 
elhárításának lehetıségeire. Beregszász [Beregovo, Ukraine]: 
manuscript. 40-47 

Németh E. 1959. Hidrológia és hidrometria. Budapest: 
Tankönyvkiadó. 161-210 

Oroszi V. Gy. – Kiss T. – Botlik A. 2006. A 2005. évi tavaszi 
áradás üledékfelhalmozó hatása a Maros hullámterén. III. 
Magyar Földrajzi Konferencia Budapest 2006. szeptember 6-
7. CD-ROM. 1-12    

Rátky I. – Farkas P. 2003. A növényzet hatása a hullámtér 
vízszállító képességére. Vízügyi Közlemények 85/2: 246-265 

Steiger J. – Gurnell A. M. 2002. Spatial hydrogeomorphologi-
cal influences on sediment and nutrient deposition in riparian 
zones: observations from the Garonne River, France. Geo-
morphology 49: 1-23 

Walling D. E. – He Q. 1998: The spatial variability of over-
bank sedimentation on river floodplains. Geomorphology 
24/2-3: 209-223 

Werner M. G. F. – Hunter, N. M. – Bares, P. D. 2005. Identifi-
ability of distributed floodplain roughness values in flood 
extent estimation. Journal of Hydrology 314: 139-157 

Wyzga B. 1999. Estimating mean flow velocity in channel and 
floodplain areas and its use for explaining the pattern of 
overbank deposition and floodplain retention. Geomorpho-
logy 28: 281-297 

Zhao Y. – Marriott S. – Rogers J. – Iwugo K. 1999. A prelimi-
nary study of heavy metal distribution on the floodplain of 
the River Severn, U.K. by a single flood event. Science of the 
Total Environment 243-244: 219-231