Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

 5 

THE QUALITY OF THE SIRET RIVER IN SIRET SECTION  
SIMILARITIES AND DIFFERENCES OF THE RESULTS OBTAINED FOR THE 
SAMPLES COLLECTED IN COMON BY THE ROMANIAN AND UKRAINIAN 

 
Doina MIHĂILĂ 

 
Water System Management, Suceava, Romania, e-mail doina_mihaila@yahoo.com 

 
 
 

ABSTRACT: This article describes the evolution of water quality of Siret River at the 
entrance in Romania for a 5 years period. The correlation of the determined physical, chemical and 
biological indicators offer an overall image of their season, annual and multi-annual variation but 
also their ranging into quality classes. 

The comparative study of the results obtained by the Romanian and the Ukrainian side for the 
samples collected in common, highlights the similarities and differences between the methods and 
methodologies used in analyzing water quality of the two countries. 

 
Keywords: analysis, indicators, concentration. 
 
 

 
Introduction 

 
Assessment of water quality into 

the Siret River in Romania is achieved by 
monitoring surface water quality. 

The purpose of monitoring is to 
know the effect of the pollution sources 
and cleaning, in order to take the 
immediate and future measures for the 
protection of water resources and for the 
checking of the measures which have been 
taken. 

Water quality analysis is monitored 
by physical, chemical and biological 
analysis on certain points and with a 
certain frequency. 

Types of the monitoring programs 
and number of sections monitored by the 
SGA Suceava in the water quality 
laboratory (Directiva 2000/60/CE) are 
presented in Table. 1 

Determination of water quality in 
terms of physical and chemical indicators 
is correlated with the biological analyses, 
the environmental conditions having a 
major influence on benthic fauna, thus 
obtaining a complete picture of it (ord. 
161/2006). 

Table 1 
 Monitoring programs and monitoring section 

number 
Number of sections monitored Monitoring 

programs River Lake Groun-
dwater 

Waste 
water 

Surveillance 13 13 155 - 
Operational 15 4 23 46 
Drinking 7 2 8 - 
Reference 4 1 - - 
Ichthyofauna 23 13 - - 
Vulnerable 
areas 

3 - 38 - 

Protection of 
habitats and 
species 

2 5 - - 

International 
Conventions 

1 - - - 

 
The monitoring of Siret River at the 

border is carried out jointly with the 
Ukrainian side based on a cooperation 
protocol, which provides water sampling 
from the Siret river at the border, in order 
to establish quantities of existing pollutants 
in the river, at the transit of the two 
countries. [1] 

We used the data base of physical, 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

 6 

chemical and biological indicators for the 
period 2004-2008 obtained from the 
archives of Suceava Water Management 
System, in order to make a classification 
on quality classes. [2] 

The framing in quality classes was 
done under the Order 161/2006 concerning 
the chemical elements and the chemical 
and physical-chemical quality standards in 
surface water. The results and conclusions 
we reached are set out below 

 
Experimental 

 
Basic methods for studying the 

evolution of river water quality during a 5 
year period were: the processing of 
experimental data, analysis, graphical 
methods of data analysis, analytical 
comparison. [3-8] 

It was considered a mediation of 
multiannual values to see the progress in a 
period exceeding one year, to eliminate the 
inherent variations due to a complex 
overlapping of hydrological, physical, 
chemical, biological and technical factors.  

 
1. Physical-chemical analyses 

1.1 pH 
Measure the activity of hydrogen ions 

(SR ISO 10523/1997), the normal range of 
variation of pH is between 6,5-8,5 pH 
units. 

Values in the last 5 years fall within the 
range noted, however, the 2008 average of 
8.12 pH Units is slightly higher than 
during previous years. 

The values recorded (Fig. 1) have 
no dramatic developments, the range of 
values generally ranging between 7 and 8.3 
pH Units. It is noted that most values are 
higher than 8, at the upper part of the 
range, which means a trend of slight 
alkaline water. The minimum value of pH 
was 6.8 and it was registered in May 2004 
and the maximum value was registered 
also in2004 but in November the same 
year, having the largest amplitude.  

Comparatively, in the graphical 
representation it can be observed that the 
values determined by Ukrainian side are 
consistently higher, but they do not exceed 

6,5

6,9

7,3

7,7

8,1

8,5

I F M A M I I A S O N D

p H units
2008

2007

2006

2005

2004

Monthly
average

 
Fig. 1 Annual evolution of pH values on section 

Siret - Siret (2004-2008) 
the maximum permitted by the applicable 
law (Fig. 2). 

7,5

8

8,5

I F M A M I I A S O N D

 pH Units

Rom ania Ucraina
 

Fig. 2  Comparative evolution of pH values on 
section Siret - Siret (2008) 

 
1.2 Dissolved oxygen 

As a dissolved gas, oxygen behaves 
as such: with increasing temperature in the 
summer, the concentration decreases, then 
increase during the cold period of the year. 

The amount of dissolved oxygen in 
water varies according to atmospheric 
pressure, water temperature, the content of 
mineral salts and organic substances (SR 
EN 25814 ISO 5814/ -1999). This concave 
variation is unchanged; the minimum 
values determined are invariably recorded 
each year in the hot season as seen in 
Fig.3. Even in summer, the minimum 
concentrations recorded (7.93 mg/l O 
September 2007) included the river in class 
II, which means water with a good 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

 7 

ecological status.  
The variations in time of the values 

for dissolved oxygen are dependent on: 
- the amount of oxygen resulting from 
photosynthesis 
- oxygen consumption of organisms in the 
ecosystem 
- temperature, depth and stratification of 
water 
- load of organic substances of Water  
- loads strong reducing agents of water 

7

8

9

10

11

12

13

14

15

I F M A M I I A S O N D

Class I 

mgO/l 2008

2007

2006

2005

2004

Class  I

Monthly
average

 
Fig. 3 Annual dissolved oxygen regime on Section 

Siret - Siret (2004-2008) 
 

Fig. 4 shows the dependence of 
dissolved oxygen on the content of organic 
matter and temperature: with the arrival of 
the warm season the amount of organic 
matter present in water increases due to 
weaker amount of dissolved oxygen. 

2

4

6

8

10

12

14

I F M A M I I A S O N D

mgO/L
Monthly
ave rage
Dissolved
Oxygen

Monthly
ave rage
CCOCr

 
Fig. 4 Comparative evolution of the monthly 

averages for dissolved oxygen and COD the Siret - 
Siret section - 2008 

For the samples collected in common we 
have: 
- Average values for 2008:Romania - 10,53 
mg/l, Ucraina - 9,82mg/l,  

- Maximum for 2008 Romania - 
13,19mg/l, Ucraina - 13,09mg/l, 
- Minimum 2008 Romania - 8,33mg/, 
Ucraina - 6,08mg/l (Trufaş 2003) 

Class II

5

7

9

11

13

15

I F M A M I I A S O N

Class I

mgO/l

Romania Ucraina  
Fig. 5 Comparative evolution of the concentration 

of dissolved oxygen - section Siret Siret (2008) 
 

The differences in evolution of the 
dissolved oxygen appear at the minimum 
values recorded of the two countries, is 
generally due to samplings techniques and 
transportations. 

 
1.3 Chemical oxygen demand (COD) 

COD puts into evidence the amount 
of organic matter present in water oxidable 
with K2Cr2O7 (ISO 15705:2002). 

The COD (quantity of organic 
matter) does not exceed the limits of Class 
II. High concentrations are generally 
reported in June, July, August. 

During the cold of the year when 
the activity of micro organisms is reduced, 
flow rates are relatively constant, the 
amount of organic matter is low, and CODr 
variations are insignificant. In the studied 
period, the maxims values do not exceed 
class II , which means a good ecological 
status (Mănescu 1994).  

Graphical representation of mean 
monthly values of the studied period (fig. 
6) shows that in warm months registers a 
slight increase, and the maximum values 
do not exceed class II, therefore showing a 
good ecological state.  

Monthly peaks have a similar 
running of the minima, the background 
thermal and flow variations. 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

 8 

 
Fig. 6 The average change, monthly minima and 

maxims on COD values Section Siret - Siret  
(2004-2008) 

 
1.4 Biochemical oxygen demand (BOD5) 

BOD5 basic element in the 
correlation between the amount of organic 
matter existing in the water and biological 
activity of micro organisms (SR EN 1899-
1/2003), the maximum values was 
recorded in June, July, August. The mean 
in the period under review shows an 
increase in June, July, August and a 
decrease in winter.  

Class I

0

2

4

6

8

10

I F M A M I I A S O N D

Class II

mgO/l

Class  III 2008
2007 2006
2005 2004
Monthly averages

Clas s  III

 
Fig. 7 Evolution BOD5 concentration on Section 

Siret - Siret (2004-2008) 
It is observed (Fig. 7) so that during 

the summer months high temperatures and 
intense biological activity had put their 
mark on the BOD5 values meaning an 
increase value and significantly lower 
values in winter. During the studied period, 
there is a similarity between the evolution 
of average COD (Fig. 6) and BOD5 (Fig. 
7), in both cases the maximum values were 
recorded during the summer months, once 
with an increased amount of organic 
substances in water. 

Clas s II

0

1

2

3

4

5

I F M A M I I A S O N D

Class I

mg O/l

Romania Ucraina  
Fig. 8 Comparative evolution of the concentration 

of BOD5 in Section Siret - Siret (2008) 
It can be observed the increase of 

maximums in the warm period in June, 
July, August generally. The highest value 
was determined in 2006, reaching a 
maximum value of 8.04 mg/l, which has 
put the river (ord.161/2006) in IVth quality 
class (Fig. 7). 

In 2008 the results obtained by the 
two countries have a similar trend, the 
difference from the results recorded in 
February and March does not change the 
class of the river (Fig 8). 
 
1.5 Ammonium nitrogen (N-NH4) 

Variations concentration of 
ammonium ion in the studied period, are 
not dependent by temperature regime as  

Clas s I 

0

0,1

0,2

0,3

0,4

0,5

0,6

I F M A M I I A S O N D

Class  I

                                
mg N - 
NH4/l   

2008

2007

2006

2005

2004

Mon thly
aver age

 
Fig. 9 Evolution of the concentration of N-NH4 by 

Section Siret - Siret (2004-2008) 
shown and do not exceed the limit value of 
0.4 mg N/L for class I. The maximum 
recorded value was 0.498 mg N / l, which 
means one II class - good ecological status. 

It is interesting the comparison 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

 9 

between the values determined by the two 
laboratories since they use two different 
methods (fig.10). 

0

0,1

0,2

0,3

0,4

I F M A M I I A S O N D

Class I

mg N - NH4 / l

Romania Ucraina Class I

 
Fig. 10 Comparative evolution of the concentration 

of N-NH4 in Section Siret - Siret (2008) 
 

Ukrainian part determined the ion 
ammonium content by treating the sample 
with Nessler reagent (STAS 6328/85) and 
this method is not so sensitive for low 
concentrations, and the Romanian side had 
determined the ion ammonium content by 
the reaction of ammonium ions content 
salicylate and hypo-chlorite in the presence 
of sodium nitroprusiat (SR ISO 7150-
1/2001) (the method using Nessler reagent 
is repealed due to its toxicity and because 
the method with the nitroprusiat obtain 
better performance at low levels). 
 
1.6 Nitrogen from nitrates and nitrites 
(N - NO2, şi N – NO3) 
The presence of nitrites in water is 
generally due to the existence of 
insufficiently treated sewage (Mănescu, 
1994). Regarding the N-NO2 concentration 
variation, in October 2005 it was recorded  
a maximum value of 0.072 mg / l N which 
includes the river in class IV, the maximum 
frequency values during the studied period 
being up to the concentration of 0.03 mg 
N/l. When referring to N-NO3 
concentration, it can be observed a slight 
increase during cold, season plateau of 
variation is generally up to 2 mg / l. 

Class II

0
0,01
0,02
0,03
0,04
0,05
0,06
0,07
0,08

I F M A M I I A S O N D

C l ass  IIImg N-NO2 / l

2008 2007
2006 2005
2004 Month l y ave rage

 
Fig. 11 Evolution of the concentration of N-NO2 by 

section Siret - Siret (2004-2008) 
 

 Class II

0

1

2

3

4

I F M A M I I A S O N D

Class I

mg N-
NO3/l

Maximum monthly Minimum monthly Average monthly
Class I Class I  

Fig. 12  The average change, monthly minima and 
maxims on N-NO3 by section Siret - Siret  

(2004-2008) 
 

Class II

0

0,01

0,02

0,03

I F M A M I I A S O N D

mg N-NO2/l

Romania Ucraina  
Fig. 13 Comparative evolution of concentration 

 N-NO2 by Siret - Siret section – 2008 
A single maximum of 3.42 mg / l 

was recorded in February 2007, and then 
the river is included in class III 
(ord.161/2006). When referring to 
concentration N-NO2 there are sensitivity 
differences between the used methods. 

For nitrates (fig.14) it is showed a 
similar trend (no significant differences) of 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

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Class I

0

1

2

3

I F M A M I I A S O N D

mg N-NO3/l

Class II

Romania Ucraina
 

Fig. 14 Comparative evolution of N-NO3 in 
Section Siret - Siret (2008) 

nitrates concentration recorded by the two 
laboratories, since the principle of 
determining the methods used is identical. 
 
1.7 Total mineral nitrogen, total 
phosphorus 

For total mineral nitrogen, the 
quality class determined according to 
values is of maximum II, the maximum 
concentration recorded being 1.28 mg N/l. 

Class I

0

0,15

I F M A M I I A S O N D

mg P/l

2008 2007
2006 2005
2004 Monthly average

Fig. 15  Evolution of the concentration of P in 
Section Siret - Siret (2004-2008) 

For the samples collected in 
common, the variability of determined 
values falls within ± 0.29 mg N/l, the large 
differences are recorded in November and 
October. 

Determined values for total P did 
not exceed class II (0.4 mg P/l) generally 
the variation values ranging up to 0.15 
mgP/l (class I). 

It is noted that during the monitored 
 

Table 2 
 Comparative values of total mineral N 

concentration in 2008 
Monthly Romania 

mg N/l 
Ucraina 
mg N/l 

January. 1.112 1.219 
February 1.13 1.379 
March 0.82 0.084 
April 1.076 1.119 
May. 1.284 1.559 
June 0.748 0.81 
July 0.71 0.599 

August 0.634 0.779 
September 1.275 1.03 

October 0.708 0.989 
November 0.753 1.039 
December 0.811 0.999 

period only during September 2006 it was 
recorded a value of 0,183 mg P/L, which 
included the river in class II (fig.15). 

Analyzing the values for 
phosphorus from orthophosphate, from 
both laboratories (Fig. 16), it can be 
observed that concentrations do not exceed 
class II (ord161/2006). 

Class I

0 0,15 0,3

I

M

M

I

S

N

Class II

m g P-PO 4/l

Romania Ucraina
 

Fig. 16 Comparative evolution of the concentration 
of P-PO4 in Section Siret - Siret (2008) 

We can differentiate the fact that 
the values obtained by the Romanian side 
are constant in class I and those obtained 
by the Ukrainian side had higher values but 
also with different trend. In this case, the 
class of quality obtained by the two 
laboratories is different, but the ecological 
status of the river is good. 
 
1.8 Iron  

The General area of variation of the 
concentration of iron is frequently included 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

 11 

between 0 and 0.3 mgFe / l, which 
corresponds to quality class I. 

Class I

0

0,1

0,2

0,3

0,4

0,5

I F M A M I I A S O N D

Class II

mg Fe/l

max min
Class I Monthly average

Fig. 17 Evolution maxims, minima and average 
monthly concentration of Fe on Siret - Section Siret 

(2004-2008) 
Fig. 17 shows that values exceeding 

class I are very rarely recorded: thus we 
have a maximum of 0.48 mg / l in March 
2005 and another value of 0.34 mg Fe / l in 
May 2008, which implies a class II of the 
river on the analysis of daily samples. 

Monthly average values indicate a 
decrease of the iron concentrations in 
general during the months of July, August, 
September, higher values being recorded 
during the cold months of the year: 
January, February, March, December 
(archive SGA Suceava). 

The trend of the values obtained by 
the two countries in iron determination is 
similar, with no major differences. 
 
1.10 Other metals 

Among the metals determined by 
the Romanian part we mention: beryllium, 
boron, aluminum, titanium, vanadium, 
chromium, manganese, cobalt, nickel, 
copper, zinc, arsenic, selenium, 
molybdenum, silver, cadmium, tin, 
antimony, tellurium, barium, mercury , 
cadmium, titanium, lead, uranium. 

The only element which was 
overrun is tin found, the value determined 
is 4.9 mg / l and the limit is 2.2 mg/l 
(ord.161/2006). 
 
1.11 Priority and priority hazardous 
substances 

The indicators analyzed include the 
determination of chlorobenzenes group 
(Pentachlorobenzene, Trichlorobenzenes, 

Hexachlorobenzene, Endosulfan,) 
pesticides (Alachlor, Aldrin, Lindan, 
Isodrin, Dieldrin, Endrin) herbicides, 
insecticides and fungicides with N and P 
(Chlorpyrifos, Chlorfenvinphos, 
Trifluralin, Atrazine, Simazine, 
Benzo(k)fluoranthene, Benzo(a)pyrene, 
Benzo(b)fluoranthene, Benzene, 
Anthracene, Naphthalene, Polyaromatic 
hydrocarbons, Lead, Mercury, Nickel, 
Benzo(g,h,i)perylene, Indeno(1,2,3-
cd)pyrene. 

The values obtained for these 
determinations by atomic emission 
spectrometry technique with inductively 
coupled plasma, there are not exceed ances 
of the allowed concentration limits 
 
2. Biological determination 

In order to determine the factors 
who modify the water quality, the 
biological methods are based on the 
relationships between organisms and  
abiotic conditions. The living creatures 
who lived in those waters form two distinct 
types of biocoenosis - the plankton, less 
represented by organisms and the benthic 
organisms, abundant, varied. The benthic 
biocoenosis is represented by benthic algae 
and benthic macroinvertebrates (Antonescu 
1963).  

Table 3  
Classes of surface water quality by saprobic index 

(ord.161/2006) 
Saprobic 
index Contamination 

Quality 
class 

Ecological 
status 

<1,8 Contamination absent, weak I Very good 

<2.3 Moderate pollution II Good 

<2.7 Moderate to critical pollution III Moderate 

<3.2 Strong contamination IV Poor 

>3.2 Strong contamination V Bad 
Among the analysed bioindicators, 

the benthic macroinvertebrates of rivers 
have specific characteristics depending on 
the characteristic of the substrata, water 
velocity, water chemistry and the river 



Journal Food and Environment Safety of the Suceava University – FOOD ENGINEERING, 
 Year IX, No1 - 2010 

 

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benthos are poorer than in streams benthos. 
Phytobenthos is represented by 

benthic  autotroph algae. Their major role 
is the synthesis of organic substances from 
water and are the basis of most food chains 
in the water. After the identification of  
these organisms we are making  an 
assessment of water quality, due to rapid 
response of organisms to changes in 
environmental conditions, calculating the 
saprobic index. In according with Order 
161/2006 and saprobic index  we establish 
following  water quality class (table 4): 

Table 4 
 Quality classes depending on Siret -Siret section 

biomarkers (2004-2008)  

Indicator 2004 2005 2006 2007 2008 

River Siret – Siret       Quality class 
Plankton II II II II II 
Zoobentos  II II II II II 
Benthic 
algae II II II - - 

Depending of biological analysis in 
the section examined we distinguish a high 
diversity of organisms, the number and 
diversity is close related with the 
characteristic of the substrate and the water 
chemistry. 
      1 The planktonic biocoenosis is 
reprezented by taxonomic groups: 
Bacillariophyceae, Euglenophyta şi 
Clorophyceae 
      2 The benthic algae are represented by 
taxonomic groups: Bacillariophyceae, 
Cyanophyceae 
      3 The zoobenthos is represented by 
taxonomic group: Ephemeroptera, 
Trichoptera, Diptera (SGA Suceava 
archive) 
 

Results and discussion 
 

The data presented in this material 
can be concluded: 
- The general physical-chemical indicators 
make the ranking of the river in class II - 
according to the annual average (2004-

2008), (Order 161/2006 art. 6. 1 letter a), 
- Concentrations determined from metal 
and priority hazardous substances do not 
show value that exceeds the allowed limits, 
- Biomarkers values are in close 
correlation with the physical, chemical, 
including the river in grade II. 
- Environmental status of the river is good 
- For the samples collected in common 
with the Ukrainian side, the differences 
arising between the analytical results are 
due to different sensitivity of different used 
methods and equipment. 
 

Conclusions 
 

The conclusion is that for those 5 
monitored years, there were not changes in 
the quality class of the river, because 
industrial activity upstream did not 
increase in intensity amid economic 
stagnation Chernivtsi region of Ukraine, 
and due to increased capacity Self-
purification generated large flows of this 
river. 

References 
 

1. C. ANTONESCU, Biologia Apelor, Editura 
Didactică şi Pedagogică Bucureşti, 1963 
2. S. MĂNESCU, M. CUCU, MONA LIGIA 
DIACONESCU, Chimia sanitară a mediului, 
Editura medicală Bucureşti, 1994 
3.  V. TRUFAŞ, C. TRUFAŞ, Hidrochimie Ediţia a 
II a, Editura Agora Călăraşi, 2003 
4. ***Buletine de analiză a apei pentru râul Siret 
secţiunea Siret din perioada 2004-2008, arhiva 
Sistemului de Gospodărire a Apelor Suceava  
5. ***Directiva Cadru privind Apa 2000/60/CE  
6. ***Geografia României, I, Geografie fizică, Edit. 
Academiei Române, Bucureşti, 1983 
7. ***Ordinul 161/2006 pentru aprobarea 
Normativului privind clasificarea calităţii apelor de 
suprafaţă în vederea stabilirii stării ecologice a 
corpurilor de apa 
8. *** ISO 15705:2002, SR EN 25814 ISO 
5814/1999, SR EN 1899-1/2003,SR ISO 10523/ 
1997, SR ISO 8466–1/1999, SR ISO 7150-1/2001, 
SR EN 26777:2006, SR ISO 7890-3/2000, SR ISO 
7890-1/1998, SR EN ISO 6878/2005, SR ISO 
6439:2001 /C91:2006, ISO 15705:2002, SR ISO 
6332-19