Difference between revisions of "Baltic Sea"

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===Eutrophication===
 
===Eutrophication===
From drainage area populated by over 80 millions people<ref>http://en.wikipedia.org/wiki/Baltic_Sea#Land_use</ref> Baltic Sea receive load of phosphorus as high as 32,9*10<sup>3</sup>[t*y<sup>-1</sup>] and 661,8*10<sup>3</sup>[t*y<sup>-1</sup>] of nitrogen (means for decade 1994-2004) <ref>HELCOM Indicator Fact Sheets 2005. Online. http://www.helcom.fi/environment2/ifs/en_GB/cover/</ref>. [[Image:pustynie tlenowe-1.jpg|thumb|right|Figure 6: Oxygen depleted and anoxic zones at the bottom]] These loads shows generally decreasing trends but in Baltic Proper and Gulf of Bothnia were still increasing while in other parts decreased 7. High waterborne nutrient load (4kg phosphorus and 83kg nitrogen per capita) results in high winter concentrations in water column - >15&mu;g*dm<sup>-3</sup> inorganic phosphorus and >60&mu;g*dm<sup>-3</sup> inorganic nitrogen in prevailing area of the sea only in Gulf of Finland and some coastal zones these values are higher <ref>The Baltic Marine Environment 1999-2002. 2003. Baltic Sea Environment Proceedings No. 87, pp. 1-47 (http://meeting.helcom.fi/c/document_library/get_file? _l_id=79889&folderId=377779&name=DLFE-36818.pdf</ref>. Excess of nutrients cause beside spring and autumnal primary producers blooms (mainly diatoms), summer ones dominated by cyanobacteria and dinoflagellates (causing sometime “red tides”). High and rapid biomass production results in high flux not consumed organic carbon fall passing by lid of halocline and in decomposition processes cause oxygen depleted “death zones” (Fig. 6).  
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From drainage area populated by over 80 millions people<ref>http://en.wikipedia.org/wiki/Baltic_Sea#Land_use</ref> Baltic Sea receive load of phosphorus as high as 32,9*10<sup>3</sup>[t*y<sup>-1</sup>] and 661,8*10<sup>3</sup>[t*y<sup>-1</sup>] of nitrogen (means for decade 1994-2004) <ref>HELCOM Indicator Fact Sheets 2005. Online. http://www.helcom.fi/environment2/ifs/en_GB/cover/</ref>. [[Image:pustynie tlenowe-1.jpg|thumb|right|Figure 6: Oxygen depleted and anoxic zones at the bottom]] These loads shows generally decreasing trends but in Baltic Proper and Gulf of Bothnia were still increasing while in other parts decreased. High waterborne nutrient load (4kg phosphorus and 83kg nitrogen per capita) results in high winter concentrations in water column - >15&mu;g*dm<sup>-3</sup> inorganic phosphorus and >60&mu;g*dm<sup>-3</sup> inorganic nitrogen in prevailing area of the sea only in Gulf of Finland and some coastal zones these values are higher <ref>The Baltic Marine Environment 1999-2002. 2003. Baltic Sea Environment Proceedings No. 87, pp. 1-47 (http://meeting.helcom.fi/c/document_library/get_file? _l_id=79889&folderId=377779&name=DLFE-36818.pdf</ref>. Excess of nutrients cause beside spring and autumnal primary producers blooms (mainly diatoms), summer ones dominated by cyanobacteria and dinoflagellates (causing sometime “red tides”). High and rapid biomass production results in high flux not consumed organic carbon fall passing by lid of halocline and in decomposition processes cause oxygen depleted “death zones” -  currently covering about 25% of  total area of Baltic Sea bottom<ref>Bonsdorff, E., C. Ronnberg & K. Arnio, 2002, Some ecological properties in relation to eutrophication in the Baltic Sea. Hydrobiologia 475/476, pp 371-377</ref> (Fig. 6).  
More visible – for seashore visitors – is eutrophication effect in the coastal zone. Here apart cyanobacterial and red tides massive development of filamentous algae – mainly Ectocarpaceae – forms awfully looking algal mats, in late phase of development floating and finally ending at the shore or at the bottom covering all living organisms competing for oxygen during decomposition.  
+
More visible – for sea shore visitors – is eutrophication effect in the coastal zone. Here apart cyanobacterial and red tides massive development of filamentous algae – mainly Ectocarpaceae – forms awfully looking algal mats, in late phase of development floating and finally ending at the shore or at the bottom covering all living organisms competing for oxygen during decomposition.  
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Revision as of 16:22, 26 April 2009

Local environment

Definition and basic facts

Figure 1:Baltic Sea and its Drainage area[1]
The Baltic Sea – a shallow, epicontinental sea of volume 21,700 km3 , with a drainage area of ~1.7 million km2 - is one of the largest brackish seas in the world. Drainage runoff (660 km3 per year) exceeds ten times precipitation (if exclude evaporation) and makes up 2% of sea volume. Baltic is situated between 100 E ~54oN and ~310E to 660N (close to Arctic Circle) being under influence of mild Atlantic climate in south-west end to harsh continental – boreal climate in Bothnian Bay area. It is connected with Atlantic Ocean through system of very narrow and shallow straits (Great Baelt, Øresund and Little Baelt).
Table 1. Basic data of the Baltic Sea not included in the text (after Bonsdorff et al., 2002[2]).
Parameter Measure
Area

415 000km2

Length

1300 km

Width

1200km

Maximum depth

459m

Sill depth

17m

Residence time of water

25yr

Stratification and circulation

Figure 2:Salinity gradient

Restricted connection with open seas, together with high riverine inflow, results in something like backwater effect of water in the whole basin – In Gulf of Bothnia water level is 36cm higher than in North Sea, in middle part of Baltic Proper by 18 and in Kattegat by 10cm. This generate strong current in Sound system. Inversely enters weaker (roughly twofold) current bearing saline (<34PSU) waters from North Sea. Such balance of fresh vs. Saline waters – characteristic for estuaries – cause permanent strong salinity gradient. At entrance – in Kattegat – salinity of surface waters is around 20PSU but in Bornholm Basin decrease to 8PSU and even lower at North and East periphery (Fig.2). This estuarial feature is expressed also in vertical stratification of the water column and permanent halocline is present along whole Baltic Sea, it is located at 40-60m at Western end and 60-80 at Northern part. As an effect of such stratification is existence of two types of water masses – relatively light freshened surface – and heavier more salty deep waters.

Coasts

Figure 3: Inhabitants of sandy coasts

Southern part of the Baltic Sea is fringed mainly by coasts built of sedimentary material – leftovers after glacial time. Composed mainly of sand, are vulnerable to mechanical stress of wind and wave action and due to its mobility is not conducive to seaweeds and vascular plant development, also only infaunal or meibenthic animals can endure here (Fig.3). Coastline here is rather straight and exposed, only in estuaries or supports shelters for flora .

Figure 4: Inhabitants of rocky coasts

In contrast Northern and North-East Baltic (partly Gulf of Finland, and Bothnia and Swedish coast) are mainly composed of rocky substratum, shoreline is well developed with fiords, coves and archipelagos - superb shelter for vegetation and associated fauna (Fig.4).

Primary production

Characteristic feature of primary production in Baltic Sea is its seasonality and spatial variability. Spring bloom – main pulse of new organic matter in higher latitudes starts in February March in Westernmost while in Northern part, in May. Annual primary production vary from 500 [gC*y-1 *m-2] in Danish fjords to [50 gC*y-1 *m-2] in open waters of Western part of Baltic Proper (Rydberget al. 2006 [3]) in Gulf of Gdańsk annual primary production is as high as ~200[gC*m-2y-1] (Lorentz et al. 1991[4]) and well below 100[gC*m-2y-1] in Northern part of the Sea (Kangas et al. 1993,[5]). This decreasing trend reflects both salinity and climatic gradients. Characteristic feature for Baltic is third - Summer bloom of Cyanobacteria - in addition to typical for temperate seas Autumnal bloom.

Specific biodiversity issues

Figure 5: Decline of number of taxa along salinity gradient

The marine–brackish–limnic conditions in the area established about 8000 years, and the current regime in terms of salinity and basic climatological conditions (covering six zones, from the temperate to the subarctic) is about 3000 years old (Bonsdorff 2006[2]. In compare with other similar seas , due to its brackish characteristic, Baltic Sea is inhabited by animals, protists and plants representing relatively lesser number of taxa, but sometime represented by many individuals. While most diverse marine ecosystems consists of 800 taxa of macrofauna per 10 m2 - in Baltic one can expect no more than 30 taxa. But from other side, the flora and fauna of the Baltic is unusual in that there are areas in which freshwater, brackish water and marine species co-exist. For example, the freshwater plant - common reed (Phragmites australis) and the marine wrack (Fucus vesiculosus) can be found side by side or fresh water species of phytoplankton exists beside “fully marine” ones (~20 marine, 20 fresh and 30 brackish water). Biodiversity follows differences of environmental factors (see above) in different part of the Baltic Sea. In Skagerrak, where a water salinity is as high as 30 PSU, some 1500 marine animal species and 154 seaweeds live. But in so far proximity - in the southern part - where salinity is much lower (10 PSU) only ~ 150 animal and less than 50 benthic alga species can be found (Kautsky et al., 1990.[6])


Threats

Eutrophication

From drainage area populated by over 80 millions people[7] Baltic Sea receive load of phosphorus as high as 32,9*103[t*y-1] and 661,8*103[t*y-1] of nitrogen (means for decade 1994-2004) [8].
Figure 6: Oxygen depleted and anoxic zones at the bottom
These loads shows generally decreasing trends but in Baltic Proper and Gulf of Bothnia were still increasing while in other parts decreased. High waterborne nutrient load (4kg phosphorus and 83kg nitrogen per capita) results in high winter concentrations in water column - >15μg*dm-3 inorganic phosphorus and >60μg*dm-3 inorganic nitrogen in prevailing area of the sea only in Gulf of Finland and some coastal zones these values are higher [9]. Excess of nutrients cause beside spring and autumnal primary producers blooms (mainly diatoms), summer ones dominated by cyanobacteria and dinoflagellates (causing sometime “red tides”). High and rapid biomass production results in high flux not consumed organic carbon fall passing by lid of halocline and in decomposition processes cause oxygen depleted “death zones” - currently covering about 25% of total area of Baltic Sea bottom[10] (Fig. 6).

More visible – for sea shore visitors – is eutrophication effect in the coastal zone. Here apart cyanobacterial and red tides massive development of filamentous algae – mainly Ectocarpaceae – forms awfully looking algal mats, in late phase of development floating and finally ending at the shore or at the bottom covering all living organisms competing for oxygen during decomposition.



References

  1. http://maps.grida.no/go/graphic/land_cover_baltic_sea_region_ balans
  2. 2.0 2.1 Bonsdorff, E., C. Ronnberg & K. Arnio, 2002, Some ecological properties in relation to eutrophication in the Baltic Sea. Hydrobiologia 475/476, pp 371-377 Cite error: Invalid <ref> tag; name "Bonsdorff" defined multiple times with different content
  3. Rydberg. L, G. Ærtebjerg , L. Edler .2006. Fifty years of primary production measurements in the Baltic entrance region, trends and variability in relation to land-based input of nutrients. Journal of Sea Research 56, pp.1–16
  4. Lorenz Z, J. Nakonieczny, S. Ochocki, H.Renk. 1991. Primary Production and Chlorophyll in the Gulf of Gdansk in 1987-1988. Acta Ichtyologica Et Piscatoria Vol. XXI Supplement pp. 117-124
  5. Kangas, P., Alasaarela, E., Lax, H.-G., Jokela, S., C., Storgård-Envall. 1993. Seasonal variation of primary production and nutrient concentrations in the coastal waters of the Bothnian Bay and the Quark. Aqua Fennica, Vol. ( 2) . pp. 165-176
  6. Kautsky H., Eddy van der Maarel. 1990. Multivariate approaches to the variation in phytobenthic communities and environmental vectors in the Baltic Sea. Mar. Ecol. Prog. Ser. 60: pp.169-184
  7. http://en.wikipedia.org/wiki/Baltic_Sea#Land_use
  8. HELCOM Indicator Fact Sheets 2005. Online. http://www.helcom.fi/environment2/ifs/en_GB/cover/
  9. The Baltic Marine Environment 1999-2002. 2003. Baltic Sea Environment Proceedings No. 87, pp. 1-47 (http://meeting.helcom.fi/c/document_library/get_file? _l_id=79889&folderId=377779&name=DLFE-36818.pdf
  10. Bonsdorff, E., C. Ronnberg & K. Arnio, 2002, Some ecological properties in relation to eutrophication in the Baltic Sea. Hydrobiologia 475/476, pp 371-377

See also

  • Baltic Marine Environment Protection Commission (Helsinki Convention)
  • An exercise in comparing the pelagic and benthic macrofauna species diversity in Arctic, Antarctic and Baltic sites using the taxonomic distinctiveness index [1]
  • Values of, and threats to, marine and coastal habitats in the southern Baltic [2]
  • Shallow sandy sublittoral: the ecological treasure of the southern Baltic Sea [3]
  • Daily sea surface temperatures rom the late 1800s to the early 2000s implications for biodiversity in the Baltic Sea [4]
  • Application of benthic indices to assess biodiversity in the southern Baltic Sea [5]


The main author of this article is Wiktor, Józef
Please note that others may also have edited the contents of this article.

Citation: Wiktor, Józef (2009): Baltic Sea. Available from http://www.coastalwiki.org/wiki/Baltic_Sea [accessed on 24-11-2024]