Sediment load of River Birs-System: Comparison
Please note this is a comparison between Version 3 by Markus R. Zehringer and Version 2 by Markus R. Zehringer.

In 2015, the environmental laboratories of the cantons of Berne, Jura, Basel-Country and Basel-City, started a coordinated monitoring of the sediments of the River Birs and its major Affluents [1]. In this report, we present the results of our investigation of the sediments for tin organics and radionuclides.

In general, stannane concentrations in the sediments of the river Birs and its major tributaries were low and well below any target values. The sediments of the tributaries Lucelle and Lüssel showed slightly elevated concentrations for monobutyl-tin, and the sediments of the rivulet Chaluet for dibutyl-tin compounds. The same stannane groups were also elevated in the sediments of the river Birs at Birsfelden, above the confluence with the Rhine. Tri-substituted tin compounds were below the detection limit in the entire catchment. The catchment area of the river Birs is free of any nuclear industry and of industries dealing with radioactive materials. Therefore, our investigations showed the “normal” background contamination with artificial radionuclides, including the global fallout and the Chernobyl fallout. The found activities are well below the immission limits.



 

[1] Bundesamt für Umweltschutz: Messung von PCBs und Dioxinen in Fliessgewässern, 2016.

https://www.bafu.admin.ch/bafu/de/home/themen/chemikalien/publikationen-studien/publikationen/messung-pcb-dioxinen-fliessgewaessern.html

 

  • Tin Organics
  • Radionuclide
  • Sediment
  • River System
  • Radiocesium

Introduction

The river Birs and its tributaries drain an area of about 900 km2 in the Jura Mountains (Northwest Switzerland). The source of the Birs is located southwest of Tavannes, canton of Berne, at the foot of the Pierre Pertuis massif. After a course of 75 km through the cantons of Berne, Jura, Solothurn, and Basel-Country, the Birs joins the river Rhine in Basel-City. The main tributaries of the Birs are the rivers Sorne, Trame, Lüssel, Lützel (Lucelle) and Scheulte. In 2009, the Construction and Environmental Protection Directorate of Basel-Country reported the contamination of Birs sediments with PCBs [1]. In 2016, the Federal Office of Environment launched an investigation to determine the degree of pollution of the river sediments with regard to PCBs and dioxins. Below the industrial site of Choindez, a hot spot of PCBs was found [2]. In 2015, the environmental laboratories of the cantons of Berne, Jura, Basel-Country and Basel-City, repeated a coordinated survey of the sediments of the Birs and its major tributaries. The approach to the investigation was integral, this time focusing on heavy metals and PCB-levels as well as a biological assessment of the sediments. In addition, sediment samples were examined for stannanes and radioactive contamination.

Sediments are the “Long-term memory” of water bodies because they act as sinks and sources for many substances of environmental concern. Lake sediments can act as a chronological diary because of the permanent sedimentation resulting in undisturbed sediment layers, which can be dated. In rivers, such sedimentation processes are normally disturbed or destroyed by flooding. Nevertheless, they are very important for the monitoring of a river. A broad range of environmental substances (e.g., heavy metals, polycyclic aromatic hydrocarbons, pesticides, organotin compounds, or radionuclides) adsorb well onto river suspended matter, which in turn deposits in the sediment compartment.

Fig 1: Catchment area of the Birs river system. Rivers are in blue. (c/o swisstopo)

Organotin compounds, or stannanes, are organic derivatives of the tetravalent tin cation, derivatized with one, two, three or four functional groups. Especially stannanes with three functional groups are used as fungicides by the textile and paper industry, for conservation of paints (anti-biofouling) and prevention of algae growth on marine vessels, and as fungicides in agriculture. Stannanes are stabilizers in polymers and can act as catalysts in chemical processes. They are also used as different salts. Take the triphenyl-tin cation as an example, with hydroxide as anion it acts as acaricide (Cyhexatin) and miticide, whereas with chloride as anion it acts as a biocide. As acetate it is used as a potent fungicide.

                       

Fig 2: Structure of Cyhexatine

Stannanes are compounds with high toxic potential for water organisms. Therefore, they were gradually banned from the market until 2003. Tributyl-tin (TBT) is one of the most toxic stannanes for our rivers and lakes. The legal limit value for TBT in surface water is 0.1 ng/L. In our investigation, we were looking for tetrabutyl-tin (TTBT) and seven derivatized tin cations: monobutyl-tin (MBT), dibutyl-tin (DBT), tributyltin (TBT), triphenyl-tin (TPT), monooctyl-tin (MOT), dioctyl-tin (DOT) and tricyclohexyl-tin (TcHT).

Radioactivity is a ubiquitous phenomenon. Radioactive elements are the source of a permanent background radiation on earth, in the atmosphere and in water. Uranium, thorium and radium are representatives of these so-called naturally occurring radioactive materials (NORM). Radioactive elements can also be technologically enriched (TENORM). On the other side, man-made radionuclides add to the radioactive contamination of our environment. Since 1945, over 900 atomic bomb tests in the atmosphere resulted in a global fallout, mainly spread across the northern hemisphere. This global fallout contained long-lived radionuclides, such as 137Cs or 90Sr. In addition, the emissions due to nuclear reactor accidents, such as in Chernobyl in 1986, increase the contamination level. In 1986, the sediments of the Rhine River contained up to 1,000 Bq/kg 137Cs [3].  Today, the radioactivity load in the sediments of the Rhine lies between 8 and 15 Bq/kg dw. This remarkable decrease of the activity is due to the half-life of 30 years and due to transport of contaminated sediments downstream to the North Sea.

Legal Basis

Stannanes with three functional groups are now banned from the market. Therefore, instead of limit values, different target values were formulated for river sediments. The International Commission for the Protection of the river Elbe (IKSE) [4] has defined 25 µg/kg for some of the stannane groups. The German Working Group on water issues (LAWA) [5] defines a target value of 2 µg/kg for tributyl- tin compounds. The ordinance for the Implementation of Water Framework Directive (VO-WRRL) [6] imposes 20 µg/kg for triphenyl-tin and 40 µg/kg for tetrabutyl-tin compounds.

In Swiss legislation, some limit values exist for dissolved radionuclides in surface waters (immission limits) [7]. These limits are based on the consummation of drinking water from such a source, supposing to lead to a maximal ingestion dose of 0.3 mSv/a. Using distribution coefficients between the water and the sediment phase (KD-values), limit values for river sediments can be estimated (Table 1).

 

IGGW  (Bq/L)

KD (L/kgDW)

IGSED (Bq/kg dw)

60Co

36

120

~ 4,000

137Cs

42

500

~ 20,000

Table 1 Derived immission limits for river sediments (IGSED). dw: dry weight. KD-values were taken from literature [8].

 

Materials and Methods

Stannanes The fractionated, dried sediment samples were extracted with acetic acid under ultrasonic conditions. Then, the organo-tin compounds were derivatised with sodium tetraethylborate to yield completely derivatised compounds. These were extracted with hexane and analysed with capillary gas chromatography. The compounds were detected with a flame photometric detector (590 nm).

Radionuclides The fractionated, dried sediment samples were weighed into petri dishes (10 g). The petri dishes were counted with gamma detectors (high-resolution Ge-detectors) for at least 48 hours. The detectors were efficiency calibrated by means of certified sources with 241Am and 152Eu (available at the Czech Metrology Institute Prague [9]). The following emission lines were used for the identification and quantification of the radionuclides: 134Cs: 569 keV (15.4), 605 keV (97.6) und 796 keV (85.5), 137Cs: 662 keV (84.6) 60Co:1173 keV (99.9) und 1333 keV (100).

 

 

 

Materials and Methods

Stannanes The fractionated, dried sediment samples were extracted with acetic acid under ultrasonic conditions. Then, the organo-tin compounds were derivatised with sodium tetraethylborate to yield completely derivatised compounds. These were extracted with hexane and analysed with capillary gas chromatography. The compounds were detected with a flame photometric detector (590 nm).

Radionuclides The fractionated, dried sediment samples were weig hed into petri dishes (10 g). The petri dishes were counted with gamma detectors (high-resolution Ge-detectors) for at least 48 hours. The detectors were efficiency calibrated by means of certified sources with 241Am and 152Eu (available at the Czech Metrology Institute Prague [9]). The following emission lines were used for the identification and quantification of the radionuclides: 134Cs: 569 keV (15.4), 605 keV (97.6) und 796 keV (85.5), 137Cs: 662 keV (84.6) 60Co:1173 keV (99.9) und 1333 keV (100).

 

Results

River Birs sediments

Stannanes In the Birs sediments, trisubstituted species, tributyl-, tricyclohexane-and triphenyl-tin compounds were below the limit of quantification (< 2 µg/kg dw). Triphenyl- and tricyclohexane tin compounds were ten times lower than their target values. The concentration of tetrabutyl-tin was even twenty times lower than the target value of 40 µg/kg dw. For mono- and diaryl stannanes the target value of 25 µg/kg dw is nowhere exceeded. The highest stannane concentrations were found in the sediments near the mouth of the Birs in Basel. Here, the proportion of treated wastewater in the river is high in comparison to the upstream reaches. The stannane concentrations were within 50 % and 60 % of the target values for dibutyl-tin monobutyl-tin compounds, respectively. Overall, a distinct point source of stannane contamination was not found in any of the Birs sediments. Tri-substituted stannanes were not detected in the entire Birs catchment area. They were not applied in the entire river catchment area. Concentration of mono- and disubsituted stannanes were slightly elevated in regions where treated wastewater is drained into the Birs River.

Birs River

sample point

Monobytyl tin

DiButyl tin

Monooctyl tin

Dioctyl tin

tributyl tin

tetrabutyl tin

tricycloheyl tin

triphenyl tin

134Cs

137Cs

60Co

 

 

µg/kg dry weight (dw)

Bq/kg dw

Location              limits

25

25

25

25

2

40

25

20

4,000

20,000

Reconvillier

1

9.5

5.5

4.9

3.1

<2

<2

<2

<2

<2

4.3 ± 2.0

<0.5

Reconvillier

2

3.2

3.9

5.5

2.5

<2

<2

<2

<2

<2

7.2 ± 2.5

<0.5

Mallerey

3

6.7

4.9

3.2

<2

<2

<2

<2

<2

<1

7.9 ± 2.1

<0.5

Court

4

5.1

<2

2.1

<2

<2

<2

<2

<2

<1

10 ± 1.8

<0.5

Choindez

5

4.8

<2

2.1

<2

<2

<2

<2

<2

<1

6.6 ±  1.1

<0.5

Riedes dessus

6

4.9

4.5

<2

2.0

<2

<2

<2

<2

<1

7.0 ± 0.8

<0.5

Zwingen

7

4.7

4.5

<2

2.2

<2

<2

<2

<2

<1

9.1 ± 0.9

0.8 ± 0.3

Birsfelden

8

15

12

3.1

4.2

<2

<2

<2

<2

<1

9.1 ± 1.0

<0.5

Table 2: Stannanes and artificial radionuclides in sediments of the Birs River.

 

Fig 2: Maximal concentrations of monobutyl-tin compounds (MBT) (c/o swisstopo).

 Radionuclides Two artificial radionuclides were detectable in the river Birs sediments. As expected, due to the global fallout and the fallout from the Chernobyl-disaster, 137Cs was present in all sediment samples (4 – 10 Bq/kg dw). In one sediment sample, sample point Zwingen, traces of 60Co were detected in the sediment. Unfortunately, this result could not be confirmed in a second sediment sample. However, the activity was well below the immission limit (4,000 Bq/kg dw). 134Cs was never detectable due to its short half-live of two years.

Sediments of Birs tributaries

Stannanes Similar to the main river Birs, tri-substituted stannanes were not detectable in any of the investigated tributary sediments (< 2µg/kg dw). Highest concentrations of monbutyl-tin compounds were found in the Lucelle (Lützel) river (14 µg/kg dw). For dibutyl-tin compounds, the highest values were found in the sediments of the Lucelle (reaching 60% of the target value) and the rivulet of Chaluet.

Radioactivity As expected, the radioactivity level of the sediments of the Birs tributaries was somewhat higher due to the lower water regime of these rivers. In one sediment sample from the river Lucelle (sample point No. 11), 60Co traces were detectable. This sample point is located just upstream of the confluence with the river Birs and in close proximity to Zwingen (sample point No.7), where 60Co was found in the Birs sediment. Again, the radioactivity was very low (2 Bq/kg dw) and could not be confirmed with a second analysis. Further on-site investigations did not result in any plausible source for the 60Co.

 

Birs river influents

sample point

Monobytyl tin

Dibutyl tin

Mono octyl tin

Di-octyl tin

tributyl tin

tetrabutyl tin

tricycloheyl tin

triphenyl tin

134Cs

137Cs

60Co

 

 

µg/kg dw

µg/kg dw

Location             limits

25

25

25

25

2

25

25

25

20,000

4,000

Lucelle, above Etang de Lucelle

9

--

--

--

--

--

--

--

--

<2

11 ± 1.9

<1

Lucelle, below Etang de Lucelle

10

--

--

--

--

--

--

--

--

<1

11 ± 1.9

<1

Lucelle above joining Birs

11

14

9.1

<2

3.0

<2

<2

<2

<2

<1

7.8 ± 1.2

1.7 ± 0.6

Lüssel, Zwingen

12

14

9.1

<2

3.0

<2

<2

<2

<2

<1

8.9 ± 0.8

<1

La Sorne, Berlincourt

13

2.1

2.3

<2

<2

<2

<2

<2

<2

<1

7.0 ± 0.8

<1

La  Sorne,           Delémont

14

7.1

7.0

<2

2.7

<2

<2

<2

<2

<1

7.3 ± 0.8

<1

La Sorne 1

15

4.5

2.6

2.5

<2

<2

<2

<2

<2

<1

14 ± 1.8

<1

La Sorne 3

16

2.3

<2

2.4

<2

<2

<2

<2

<2

<1

14 ± 1.8

<1

Rivulet  of  Chaluet

17

6.5

10

<2

<2

<2

<2

<2

<2

<1

9.2 ± 2.0

<1

La  Raus, Moutiers

18

2.6

<2

<2

<2

<2

<2

<2

<2

<1

11 ± 6.9

<1

La  Trame, Reconvilier

19

8.6

5.2

3.3

2.5

<2

<2

<2

<2

<1

18 ± 1.7

<1

La  Scheulte, Vicques

20

3.0

2.6

<2

<2

<2

<2

<2

<2

<1

8.7 ± 0.9

<1

Table 3: Stannanes and artificial radionuclides in sediments of the Birs tributaries.

 

Fig 3: Detection sites for 60Co- and elevated 137Cs-activities (c/o swisstopo).

Conclusions

In general, stannane concentrations in the sediments of the river Birs and its major tributaries were low and well below any target values. The sediments of the tributaries Lucelle and Lüssel showed slightly elevated concentrations for monobutyl-tin, and the sediments of the rivulet Chaluet for dibutyl-tin compounds. The same stannane groups were also elevated in the sediments of the river Birs at Birsfelden, above the confluence with the Rhine. This pattern is typical for a river catchment with high input of treated wastewater. Tri-substituted tin compounds were below the detection limit in the entire catchment. No hot spots were detected. Therefore, the sources of stannanes are diffuse, which results in a low overall contamination level. In order to keep the stannane concentrations this low it is important to ban the usage of PVC-pipes in the sewerage systems and to consecutively replace them with pipes made of PP and PE.

The catchment area of the river Birs is free of any nuclear industry and of industries dealing with radioactive materials. Therefore, our investigations showed the “normal” background contamination with artificial radionuclides, including the global fallout and the Chernobyl fallout. Two sampling sites showed a low activity of 60Co, but upon re-sampling these values could not be verified. However, it is interesting that the sites are geographically corresponding. Still, the found activities are well below the immission limits.

 

Acknowledments

We thank Steffi Perry for the careful review of the manuscript.

 

References

[1] Bau- und Umweltschutzdirektion: Deutlich erhöhte PCB-Belastung in Birs-Sedimenten. Medienmitteilung 8.4. 2009.

https://www.baselland.ch/politik-und-behorden/direktionen/bau-und-umweltschutzdirektion/medienmitteilungen/deutlich-erhohte-pcb-belastung-in-birs-sedimenten

[2] Bundesamt für Umweltschutz: Messung von PCBs und Dioxinen in Fliessgewässern, 2016.

https://www.bafu.admin.ch/bafu/de/home/themen/chemikalien/publikationen-studien/publikationen/messung-pcb-dioxinen-fliessgewaessern.html

[3] Haberer, Klaus: Umweltradioaktivität und Trinkwasserversorgung. Oldenbourg 1989, p.29

[4] Internationale Kommission zum Schutze der Elbe (IKSE). https://www.ikse-mkol.org/en/

[5] Bund/Länder-Arbeitsgemeinschaft Wasser (LAWA). https://www.lawa.de/

[6] Hessisches Wassergesetz vom 14.12.2010: Verordnung zur Umsetzung der Wasser-Rahmenrichtlinie (VO-WRRL)

[7] Swiss Federal Council. Radiological Protection Ordinance; 1994. Status: 26 April 2017, 4397-4398.

[8] Juranova et al. Sorption of anthropogenic radionuclides onto river sediments and suspended solids: dependence on sediment               composition. Journal of Radioanalytical and Nuclear Chemistry (2020) 324:983–991

[9] https://www.cmi.cz/