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Ein regionales Modell der westlichen Ostsee mit offenen Randbedingungen und Datenassimilation (2017)

Meier, H. E. Markus [VerfasserIn] 1963-

Kiel : Inst. für Meereskunde

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Keywords: Report ; Dissertation ; Hochschulschrift

Type of Medium: Online Resource

Pages: Online-Ressource (124 Seiten, 7 MB) , Diagramme, Karten

Series Statement: Berichte aus dem Institut für Meereskunde an der Christian-Albrechts-Universität Kiel 284

URL: https://oceanrep.geomar.de/3487/

URL: http://dx.doi.org/10.3289/ifm_ber_284

DOI: 10.3289/ifm_ber_284

Language: German

Note: Zusammenfassung in deutscher und englischer Sprache

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A new approach to model oxygen dependent benthic phosphate fluxes in the Baltic Sea (2015)

Almroth-Rosell, Elin ; Eilola, Kari ; Kuznetsov, Ivan ; [et al.]

Elsevier

In: Journal of Marine Systems, 144 . pp. 127-141.

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Publication Date: 2015-01-26

Description: Highlights • A new description of sediment phosphorus dynamics was implemented in a 3D-model. • Oxygen consumption affects oxygen penetration in coastal sediments. • Low oxygen concentrations determine the oxygen penetration in deeper water sediments. • More than 80% of the phosphorus loads (1980–2008) are retained in the Baltic Sea. • Phosphorus is released from anoxic sediments and retained in oxic sediments. Abstract The new approach to model the oxygen dependent phosphate release by implementing formulations of the oxygen penetration depths (OPD) and mineral bound inorganic phosphorus pools to the Swedish Coastal and Ocean Biogeochemical model (SCOBI) is described. The phosphorus dynamics and the oxygen concentrations in the Baltic proper sediment are studied during the period 1980–2008 using SCOBI coupled to the 3D-Rossby Centre Ocean model. Model data are compared to observations from monitoring stations and experiments. The impact from oxygen consumption on the determination of the OPD is found to be largest in the coastal zones where also the largest OPD are found. In the deep water the low oxygen concentrations mainly determine the OPD. Highest modelled release rate of phosphate from the sediment is about 59 × 103 t P year− 1 and is found on anoxic sediment at depths between 60–150 m, corresponding to 17% of the Baltic proper total area. The deposition of organic and inorganic phosphorus on sediments with oxic bottom water is larger than the release of phosphorus, about 43 × 103 t P year− 1. For anoxic bottoms the release of total phosphorus during the investigated period is larger than the deposition, about 19 × 103 t P year− 1. In total the net Baltic proper sediment sink is about 23.7 × 103 t P year− 1. The estimated phosphorus sink efficiency of the entire Baltic Sea is on average about 83% during the period.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.jmarsys.2014.11.007

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OceanRep: Article in a Scientific Journal - peer-reviewed

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Report on the nature and types of driver interactions including their potential future (2016)

Kotta, Jonne ; Almroth-Rosell, Elin ; Andersson, Helen c. ; [et al.]

EU Bonusprojekt BIO-C3

In: BIO-C3 Deliverable, D3.2 . EU Bonusprojekt BIO-C3, 110 pp.

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Publication Date: 2019-03-11

Description: The Baltic Sea is a dynamic environment responding to various drivers operating at different temporal and spatial scales. In response to climate change, the Baltic Sea is warming and the frequency of extreme climatic events is increasing (Lima & Wethey 2012, BACC 2008, Poloczanska et al. 2007). Coastal development, human population growth and globalization intensify stressors associated with human activities, such as nutrient loading, fisheries and proliferation of invasive and bloom-forming species. Such abrupt changes have unforeseen consequences for the biodiversity and the function of food webs and may result in loss of ecological key species, alteration and fragmentation of habitats. To mitigate undesired effects on the Baltic ecosystem, an efficient marine management will depend on the understanding of historical and current drivers, i.e. physical and chemical environmental conditions and human activities that precipitate pressures on the natural environment. This task examined a set of key interactions of selected natural and anthropogenic drivers in space and time, identified in Task 3.1 as well as WP1 and WP2 (e.g. physico-chemical features vs climate forcing; eutrophication vs oxygen deficiency vs bio-invasions; fisheries vs climate change impacts) by using overlay-mapping and sensitivity analyses. The benthic ecosystem models developed under Task 2.1 were used to investigate interactions between sea temperature and eutrophication for various depth strata in coastal (P9) and offshore areas (P1) of the Baltic Sea. This also included investigation on how the frequency and magnitude of deep-water inflow events determines volume and variance of salinity and temperature under the halocline, deep-water oxygen levels and sediment fluxes of nutrients, using observations and model results from 1850 to present (P1, P2, P6, P9, P12). The resulting synthesis on the nature and magnitude of different driver interactions will feed into all other tasks of this WP3 and WP2/WP4. Moreover, the results presented in this report improve the process-based and mechanistic understanding of environmental change in the Baltic Sea ecosystem, thereby fostering the implementation of the Marine Strategy Framework Directive.

Type: Report , NonPeerReviewed

Format: text

DOI: 10.3289/BIO-C3_D3.2

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