Abstract
Geological hazards may threaten human life, may result in serious property damage, and may significantly influence normal development of biota. They are caused by natural endogenic and exogenic driving forces or generated by anthropogenic activities. An interaction of geological processes and intense anthropogenic activities, e.g., construction of buildings, harbors, oil and gas pipelines, hydroengineering facilities, and land reclamation, has resulted in hazard potential, especially for the densely populated areas of the Russian Baltic coastal zone. These hazards may in addition be harmful for the sensitive ecosystem of the Baltic Sea. Mapping and assessment of the geological hazard potential should be the main objectives of an integrated management program for the protection of coastal zones. This study documents the first step in that process for the Russian sector of the Baltic Sea and its coastal zone. A major part of endogenic hazard potential both in the Kaliningrad area and in the eastern Gulf of Finland remains at low- or medium-risk levels, but analysis of the recent environmental conditions at the seabed of the Russian sector of the Baltic Sea and, especially, within its coastal zone shows that during the last years the activity of exogenic geological processes has increased significantly. The highest risk within both studied areas has been caused by coastal and bottom erosion. In addition, in shallow area near the shore bottom of the eastern Gulf of Finland, “avalanche” sedimentation and sediment pollution can produce hazardous situations as well.
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References
Aptikaev FF, Nikonov AA, Alyoshin AS, Assinovskaya BA, Pogrebchenko VV, Erteleva OO (2005) Kaliningrad earthquake of September 21, 2004, DAMAGE. International conference on earthquake engineering in 21st century (EE-21C). Institute of Earthquake Engineering and Engineering Seismology (IZIIS-Skopje), University “Ss. Cyril and Methodius”, Skopje, Republic of Macedonia, 27 August–1 September 2005
Assinovskaya BA, Novozhilova TV (2002) About a level of seismic danger of Saint-Petersburg region. Izvestiya GAO 216:394–401 (in Russian)
Assinovskaya BA, Karpinsky VV (2005) On September 21, 2004 Kaliningrad earthquake source location. In: Joeleht A (ed) The Kaliningrad earthquake September 21, 2004 workshop materials. Institute of Geology, University of Tartu. Geological Survey of Estonia, 10
Auslender VG, Yanovsky AS, Kabakov LG, Pleshivtseva ES (2002) New facts in geology of St. Petersburg. Mineral 1(4):51–58 (in Russian)
Baerens C, Hupfer P (1999) Extremwasserstände an der deutschen Ostseeküste nach Beobachtungen und in einem Treibhausgasszenario. Die Küste 61:48–72 (in German with abstract in English)
Bitinas A, Zaromskis R, Gulbinskas S, Damusyte A, Zilinskas G, Jarmalavicius D (2005) The results of integrated investigations of the Lithuanian coast of the Baltic Sea: geology, geomorphology, dynamics and human impact. Geological Quarterly 49(4):355–362
Bobykina V, Boldyrev V (2008) Tendency in shore dynamics in the Kaliningrad Oblast according to five years monitoring information. Integrated management, sustainable development indicators, spatial planning and monitoring of the South-Eastern Baltic coastal regions: materials of international conference, pp 46–47. Kaliningrad (Terra Baltica)
Bödvarsson R, Lund B, Roberts R, Slunga R (2006) Earthquake activity in Sweden. Study in connection with a proposed nuclear waste repository in Forsmark or Oskarshamn. SKB report R-06-67, Uppsala University, p 40
Boldyrev VL, Lashenkov VM, Ryabkova OI (1990) Stormy reworking of the Kaliningrad coasts of the Baltic Sea. Questions of the dynamic and paleogeography of the Baltic Sea, pp 97–127. Vilnius (in Russian)
Boldyrev VL, Ryabkova OI (2001) Coastal zone processes dynamics of the Baltic Sea (Kaliningrad region). Proceedings of Russian Geographical Society 133(5):41–48 (in Russian)
Dvernitsky BG (2007) Radon monitoring of endogenic geological processes in St. Petersburg region. Radon in geology, 16–19. Moscow
Dvernitsky BG (2009) Neotectonic risk in St. Petersburg. Proceedings of the international conference on integrating geological information in city management to prevent environmental risks (GeoInForm), St. Petersburg, pp 46–47 (in Russian)
Dzeker ES (1992) Geological hazards and risks. Environmental Geoscience (Geoekologiya) 6:3–10 (in Russian)
Dzeker ES (1994) Methodological aspects of the geological hazards and risks. Environmental Geoscience (Geoekologiya) 3:3–10 (in Russian)
Eberhards G, Grīne I, Lapinskis J, Purgalis I, Saltupe B, Torklere A (2009) Changes in Latvia’s seacoast (1935–2007). Baltica 22(1):11–22
Emelyanov EM, Blazhchishin AI, Koblents-Mishke OI, Kravtsov VA, Stryuk VL, Kharin GS (1998) Ecological and geochemical situation in the eastern Baltic Sea. Problems of investigation and protection of nature at the Curonian Spit, pp 148–187. Kaliningrad (in Russian with abstract in English)
Eremina TR, Nekrasov AV, Provotorov PP (1999) Hydrophysical processes. In: Rumyantsev VA, Drabkova VG (eds) Gulf of Finland under anthropogenic impact conditions. Institute for Lake Research, Russian Academy of Sciences, Saint Petersburg, pp 5–47 (in Russian)
Fedorov MP, Shilin MB, Gorbunov NE (2008) Ecological basis of management of natural-technogenic systems. Polytechnic University Press, St. Petersburg, 506 pp (in Russian)
Fleischhauer M (2006) Spatial relevance of natural and technogenic hazards. Natural and technological hazards and risks affecting the spatial; development of European regions. Geological Survey of Finland Special Paper 42:7–16. Espoo
Har’kina MA (2000) Ecological consequences of natural disasters. Energy 1:51–56. Moscow (in Russian)
Hutri K-L (2007) An approach to palaeoseismicity in the Olkiluoto (sea) area during the early Holocene. STUK-A222, 64 pp. Helsinki
Jensen JB, Kuijpers A, Bennike O, Laier T, Werner F (2002) New geological aspects for freshwater seepage and formation in Eckernförde Bay, western Baltic. Continental Shelf Research 22:2159–2173
Kotilainen A, Vallius H, Ryabchuk D (2007) Seafloor anoxia and modern laminated sediments in coastal basins of the Gulf of Finland, Baltic Sea. Geological Survey of Finland Special Paper 45:47–60
Krupoderov VS (1994) Scientific and methodical basis of the exogenous geological processes study. Modern problems of hydrogeology, geological engineering and ecology, pp 109–129. Moscow, VSEGEINGEO (in Russian)
Leont’yev IO (2008) Sediment budget and forecast of long-term coastal changes. Oceanologia 48(N3):467–476
Medvedev SV, Shponhoyer V, Karnik V (1965) Scale of seismic intensity MSK-64. Academy of Science of USSR, 11. Moscow
Mörner N-A (2004) Active faults and paleoseismicity in Fennoscandia, especially Sweden. Primary structures and secondary effects. Tectonophysics 380:139–157
Moskalenko PE, Zhamoida VA, Manuilov SF, Spiridonov MA (2004) The geological structure, history of geological development and potential mineral resources of the eastern the Gulf of Finland. Mineral resources of the Baltic Sea – exploration, and sustainable development, pp 135–145. Hanover
Nikonov AA, Sildvee H (1991) Historical earthquakes in Estonia and their seismotectonic position. Geophysica 27(1–2):79–93
Orviku K, Jaagus J, Kont A, Ratas U, Rivis R (2003) Increasing activity of coastal processes associated with climate change in Estonia. Journal of Coastal Research 19(2):364–375
Osipov V, Shoigu S (eds) (2002) Natural hazards of Russia, 6 volumes. KRUK, Moscow (in Russian)
Plassen L, Vorren TO (2003) Fluid flow features in fjord-fill deposits, Ullsfjorden, North Norway. Norwegian Journal of Geology 83:37–42
Pomeranets K (2005) Three centuries of Saint Petersburg floods. Saint Petersburg Art, St. Petersburg, 213 pp (in Russian)
Pruszak Z, Zawadzka E (2005) Vulnerability of Poland’s coast to sea-level rise. Coastal Engineering Journal 47(2–3):131–155
Raukas A, Huvarinen H (eds) (1992) Geology of the Gulf of Finland, 422 pp. Tallinn (in Russian)
Reading HG (eds) (1996) Sedimentary environments: processes, facies and stratigraphy, 3rd edn. Blackwell Publishing Company, Hong Kong, 688p
Rudnik VA (1996) Influence of the Earth heterogeneous geological zones. Vestnik of RAS 66(8):713–719 (in Russian)
Ryabchuk D, Sukhacheva L, Spiridonov M, Zhamoida V, Kurennoy D (2009) Coastal processes in the eastern Gulf of Finland – possible driving forces and connection with the near-shore zone development. Estonian Journal of Engineering 15(3):151–167
Ryabchuk DV, Nesterova EN, Spiridonov MA, Sukhacheva LL, Zhamoida VA (2007) Modern sedimentation processes within the coastal zone of the Kurortny district of St. Petersburg (eastern Gulf of Finland). Baltica 20(1–2):5–12
Schmidt-Thomé P (2005) The spatial effects and management of natural and technological hazards in Europe―final report of the European Spatial Planning and Observation Network (ESPON) project 1.3.1. Geological Survey of Finland, 197p. Espoo
Schmidt-Thomé P (2006) Integration of natural hazards, risks and climate change into spatial planning practices. Geological Survey of Finland, pp 1–31. Espoo
Schwarzer K, Diesing M, Larson M, Neidermeyer R-O, Schumacher W, Furmanczyk K (2003) Coastline evolution at different time scales – examples from the Pomeranian Bight, southern Baltic Sea. Marine Geology 194:79–101
Sergeev AYu, Ryabchuk DV, Zhamoida VA, Nesterova EN (2009) The impact of two newly built port terminals in the eastern Gulf of Finland on sedimentation processes and coastal zone dynamics. Estonian Journal of Engineering 15(3):212–226
Sheko AI, Krupoderov VS (1994) Assessment of hazards and risks of exogenous geological processes. Geoecology 3:11–21 (in Russian)
Sliaupa S, Pacesa A, Korabliova L (1999) Indications of seismic activity in Lithuania and adjacent Baltic Sea area. Workshop: Geoindicators. Focusing on geoindicators of relevance to Eastern and Central Europe, Vilnius, Lithuania, October 11–16, pp 40–42. http://www.lgt.lt/geoin/files/vilnius_18.pdf
Söderberg P, Flodén T (1991) Pockmark developments along a deep crustal structure in the northern Stockholm Archipelago, Baltic Sea. Beiträge zur Meereskunde 62:79–102
Spiridonov MA, Rybalko AE, Butylin VP, Spiridonova EA, Zhamoida VA, Moskalenko PE (1988) Modern data, facts and views on the geological evolution of the Gulf of Finland. Geological Survey of Finland Special Paper 6:95–100
Spiridonov MA, Ryabchuk DV, Shachverdov VA, Zvezdunov SI, Nesterova EN, Suslov G, Grigoriev A (2004) The Neva Bay environmental geology, 181 pp. St. Petersburg (in Russian)
Spiridonov MA, Ryabchuk DV, Kotilainen A, Vallius H, Nesterova EN, Zhamoida VA (2007) The Quaternary deposits of the eastern Gulf of Finland. Geological Survey of Finland Special Paper 45:5–17. Espoo
Spiridonov MA, Ryabchuk DV, Kropachev YP, Nesterova EN, Zhamoida VA, Vallius H, Kotilainen A (2008) A new map of the Neva Bay bottom sediments and technogenic objects under the result of side-scan sonar profiling. Polish Geological Institute Special Papers 23:95–107
Suslov GA, Ryabchuk DV, Nesterova EN, Fedorova EK (2008) Development of the southern coastal zone of the eastern Gulf of Finland (from Lebyazhye to the St. Petersburg flood protective dam). Polish Geological Institute Special Papers 23:109–116
Uscinowicz S, Zachowicz J, Graniczny M, Dobracki R (2004) Geological structure of the southern Baltic coast and related hazards. Polish Geological Institute Special Papers 15:95–107
Valdmann A, Kaard A, Kelpsaite L, Kurennoy D, Soomere T (2008) Marine coastal hazards for the eastern coasts of the Baltic Sea. Baltica 31(1–2):3–12
TAIEX (2008) Workshop on sea-level rise and climate change – changing processes and sustainable management of the low-lying coasts of the Baltic states, Poland and Russia – INFRA 26246 (2008) [CD-ROM], TAIEX, DG Enlargement, Palanga, Latvia
Yaduta VA (2002) The modern tectonics and stability of geological environment of the Gulf of Finland. Abstracts of all-Russian conference on the quaternary period study, 15–18. Smolensk (in Russian)
Yaduta VA (2003) Modern tectonic movements of the Earth crust in St. Petersburg and their role as geological hazards. Geologists towards 300-anniversary of St. Petersburg, pp 113–125 (in Russian)
Zhamoida VA, Ryabchuk DV, Kropatchev YP, Kurennoy D, Boldyrev VL, Sivkov VV (2009) Recent sedimentation processes in the coastal zone of the Curonian Spit (Kaliningrad region, Baltic Sea). Zeitschrift der Deutschen Gesellschaft für Geowissenschaften 160:143–157
Zilinskas G (2005) Trends in dynamic processes along the Lithuanian Baltic coast. Acta Zoologica Lituanica 15(2):204–207
Acknowledgment
The authors wish to thank their colleagues Elena Nesterova, Yury Kropatchev, and Svyatoslav Manuilov for their contribution to their studies. The authors gratefully thank Vasily Bukanov, Dmitry Kurennoy, and Igor Lysanskiy as well as the captain and the crew of RV “Risk” for their great contribution to the field work. The authors are thankful for critical comments and suggestion from R.O. Niedermeyer (Güstrow/Greifswald) and from an anonymous reviewer. Furthermore, the authors would like to thank Yulia Guseva and Ricardo Olea (Washington), who have kindly revised the language of the chapter.
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Spiridonov, M., Ryabchuk, D., Zhamoida, V., Sergeev, A., Sivkov, V., Boldyrev, V. (2011). Geological Hazard Potential at the Baltic Sea and Its Coastal Zone: Examples from the Eastern Gulf of Finland and the Kaliningrad Area. In: Harff, J., Björck, S., Hoth, P. (eds) The Baltic Sea Basin. Central and Eastern European Development Studies (CEEDES). Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-17220-5_16
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