Transcript Slide 1

High frequency biogeochemical monitoring
in a polluted water system,
the Deûle canal (Northern France)
A. Magnier1*, B. Lourino-Cabana2, E. Prygiel3, M. Arold3, LF. Artigas4, W. Baeyens1, G. Billon2, M. Elskens1, Ø. Mikkelsen5, B. Ouddane2 and J. Prygiel2,3
1*. Laboratory for Analytical and Environmental Chemistry, Vrije Universiteit Brussel, Brussels, Belgium ([email protected])
2. Laboratoire Géosystèmes, Equipe de Chimie Analytique et Marine, FRE 3298, Université Lille 1, 59655 Villeneuve d’Ascq cedex, France
3. Agence de l’Eau Artois-Picardie, Centre Tertiaire de l’Arsenal, 200 rue Marceline, B.P. 818, 59508 Douai Cedex, France
4. Laboratoire d’Océanologie et de Géosciences- UMR 8187, Station Marine de Wimereux, Université des Sciences et Technologies de Lille, France
5. Norwegian University of Science and Technology, Department of Chemistry, N-7491 Trondheim, Norway
Introduction
Study area
Industrial activities have introduced a certain level of metal pollution in river
systems. The Deûle river, which passes through a former smelting plant
(Metaleurop) near Douai city in northern France, has been impacted from 1894
to 2003 by lead and zinc discharges. Since 2003, Sita France (Suez
Environnement) via AGORA project is decontaminating the area to install ecoindustries devoted to waste recovery.
This study was done to have a better understanding of both trace metal
behavior and evolution of algae specific pigments in a polluted water system by
developing a high frequency monitoring experiment.
Sampling
point
SITA AGORA
Monitoring strategy
26,2% 29,9
24,4%
date
0
20/4
25/4
30/4
5/5
10/5
15/5
2. With voltammetric technique
Zn concentration (µg/l)
60
ICP-MS
voltammetry
50
40
30
20
10
date
2/
05
/2
00
9
4/
05
/2
00
9
6/
05
/2
00
9
8/
05
/2
00
9
10
/0
5/
20
09
12
/0
5/
20
09
14
/0
5/
20
09
16
/0
5/
20
09
/2
00
9
30
/0
4
/2
00
9
28
/0
4
/2
00
9
26
/0
4
/2
00
9
24
/0
4
/2
00
9
22
/0
4
20
/0
4
/2
00
9
0
Electrolabile fraction of Zn
measured by voltammetry
varies
with
time
and
corresponds to an average
value
of
50%.
The
electrolabile
concentrations
range from 10µg/l to 30µg/l
and show that organisms may
be exposed significantly to
Zn, and probably also to
other trace metals.
Acknowledgements
This study was supported by TIMOTHY program and by the French Water
Agency/Université Lille 1 convention. We would like to thank Suez Environnement
for the implementation of the monitoring stations on their site. And UGMM (Unité
de Gestion du Modèle Mathématique de la Mer du Nord) from Ostende to lend us
the clean laboratory.
date
700
Temperature (°C)
Conductivity (µS/cm)
12
11
10
 Temperature values increase unsurprisingly during daytime with an average
amplitude of 1,6 °C.
 Conductivity decreases during the afternoon due to CO2 consumption by
organisms which encourages pH increase.
2. Short time scale
15
10
total chlorophyll a
14
13
9
12
11
8
10
9
7
8
Oxygèn (mg/l)
dissolved O2
date
7
/2
00
9
/2
00
9
2:
36
14
:5
6
6
3:
05
6
1/
05
/2
00
9
29,1%
13
740
30
/0
4
0,05
14
720
28
/0
4
35,0%
760
30
/0
4
41,7%
15
15
:2
5
0,1
780
/2
00
9
75,3%
16
3:
45
0,15
800
29
/0
4
Labile Cd measured by DGT
represents in average 37% of the
total dissolved fraction (ICP-MS)
and may have a real impact on the
organisms because of its high
toxicity.
17
/2
00
9
Cd concentration (µg/L)
0,2
18
29
/0
4
ICP-MS
DGT
DGT2
DGT3
DGT4
DGT5
DGT6
DGT7
temperature
16
:0
5
0,25
820
/2
00
9
1. With DGT piston
19
4:
25
fL = [Me]DGT or volt. / [Me]ICP-MS
conductivity
28
/0
4
Trace metal lability
840
4/
22 09
/0 10
4/ :0
24 09 0
/0 12
4/ :0
26 09 0
/0 14
4/ :0
28 09 0
/0 16
4/ :0
30 09 0
/0 18
4/ :0
02 09 0
/0 20
5/ :0
05 09 0
/0 22
5/ :0
07 09 0
/0 00
5/ :0
09 09 0
/0 02
5/ :0
11 09 0
/0 04
5/ :0
13 09 0
/0 06
5/ :0
09 0
08
:0
0
ICP-MS measurements of trace metals (Mn, Fe,
Ni, Co, Pb, Cr, Cd and Cu) were also done on
filtrated water samples and on DGT (Diffusive
Gradient in Thin film) pistons.
1. Long time scale
20
/0
A clean lab built in a container was used to
measure trace metal concentrations (Zn, Pb and
Cu) with voltammetric technique onto an
hanging mercury drop electrode (HMDE).
Chemical and biological parameters were monitored during one month every 10
min.
/2
00
9
A monitoring station belonging to the Water
Agency “Artois-Picardie” permitted on line
measurements of physico-chemical parameters:
T, pH, dissolved O2, turbidity, conductivity, total
organic carbon, PO43-, NO3-, NO2-, NH4+,
luminosity, algae pigments.
Variations of chemical and biological parameters
Total chlorophyll a
concentration (µg/l)
A monitoring station and a clean lab were directly deployed in the field from 20th
April to 17th May 2009. Physico-chemical and biological parameters were
registered every 10mn while trace metal concentrations were measured several
times a day depending on the method used.
 Total chlorophyll a concentrations have a maximum around 13h and 16h. The
concentration starts increasing just before dissolved oxygen production.
 Maximal dissolved oxygen concentration is registered around 20h. During the
night, the absence of photosynthesis causes a decrease of [O2]diss.
 Photosynthetic production from early morning results in an increase of
dissolved oxygen around 8-9 h.
Conclusion / perspectives
 Labile metal concentrations are variable and indicate that organisms are
exposed irregularly to toxicants.
 Significant fractions of trace metals are labile in the Deûle river and the
following ranking has been established: Cu > Co > Ni = Cd >Fe > Cr .
 Primary production occurs in such polluted river and leads to pH variations that
may change the lability of trace metal within 24 hours.
 On line trace metal monitoring at high frequency is still in development in our
laboratories to better understand trace metal dynamic in aquatic environments in
relation to biological processes.