Your search keyword '"Conley, A. J."' showing total 21 results

1. Efficiency of the coastal filter: Nitrogen and phosphorus removal in the Baltic Sea.

Author

Asmala, Eero, Carstensen, Jacob, Conley, Daniel J., Slomp, Caroline P., Stadmark, Johanna, and Voss, Maren

Subjects

NUTRIENT pollution of water, BIOGEOCHEMISTRY, WATER chemistry, DENITRIFICATION

Abstract

An important function of coastal ecosystems is the reduction of the nutrient flux from land to the open sea, the coastal filter. In this study, we focused on the two most important coastal biogeochemical processes that remove nitrogen and phosphorus permanently: denitrification and phosphorus burial. We compiled removal rates from coastal systems around the Baltic Sea and analyzed their spatial variation and regulating environmental factors. These analyses were used to scale up denitrification and phosphorus burial rates for the entire Baltic Sea coastal zone. Denitrification rates ranged from non-detectable to 12 mmol N m−2 d−1, and correlated positively with both bottom water nitrate concentration and sediment organic carbon content. The rates exhibited a strong decreasing gradient from land to the open coast, which was likely driven by the availability of nitrate and labile organic carbon, but a high proportion of non-cohesive sediments in the coastal zone decreased the denitrification efficiency relative to the open sea. Phosphorus burial rates varied from 0.21 g P m−2 yr−1 in open coastal systems to 2.28 g P m−2 yr−1 in estuaries. Our analysis suggests that archipelagos are important phosphorus traps and account for 45% of the coastal P removal, while covering only 17% of the coastal areas. High burial rates could partly be sustained by phosphorus import from the open Baltic Sea. We estimate that the coastal filter in the Baltic Sea removes 16% of nitrogen and 53% of phosphorus inputs from land. [ABSTRACT FROM AUTHOR]

Published

2017

2. Long-term temporal and spatial trends in eutrophication status of the Baltic Sea.

Author

Andersen, Jesper H., Carstensen, Jacob, Conley, Daniel J., Dromph, Karsten, Fleming-Lehtinen, Vivi, Gustafsson, Bo G., Josefson, Alf B., Norkko, Alf, Villnäs, Anna, and Murray, Ciarán

Subjects

EUTROPHICATION, STRATIGRAPHIC geology, NITROGEN, ECOSYSTEM dynamics

Abstract

ABSTRACT Much of the Baltic Sea is currently classified as 'affected by eutrophication'. The causes for this are twofold. First, current levels of nutrient inputs (nitrogen and phosphorus) from human activities exceed the natural processing capacity with an accumulation of nutrients in the Baltic Sea over the last 50-100 years. Secondly, the Baltic Sea is naturally susceptible to nutrient enrichment due to a combination of long retention times and stratification restricting ventilation of deep waters. Here, based on a unique data set collated from research activities and long-term monitoring programs, we report on the temporal and spatial trends of eutrophication status for the open Baltic Sea over a 112-year period using the HELCOM Eutrophication Assessment Tool ( HEAT 3.0). Further, we analyse variation in the confidence of the eutrophication status assessment based on a systematic quantitative approach using coefficients of variation in the observations. The classifications in our assessment indicate that the first signs of eutrophication emerged in the mid-1950s and the central parts of the Baltic Sea changed from being unaffected by eutrophication to being affected. We document improvements in eutrophication status that are direct consequences of long-term efforts to reduce the inputs of nutrients. The reductions in both nitrogen and phosphorus loads have led to large-scale alleviation of eutrophication and to a healthier Baltic Sea. Reduced confidence in our assessment is seen more recently due to reductions in the scope of monitoring programs. Our study sets a baseline for implementation of the ecosystem-based management strategies and policies currently in place including the EU Marine Strategy Framework Directives and the HELCOM Baltic Sea Action Plan. [ABSTRACT FROM AUTHOR]

Published

2017

3. Effects of wastewater treatment plant effluent inputs on planktonic metabolic rates and microbial community composition in the Baltic Sea.

Author

Vaquer-Sunyer, Raquel, Reader, Heather E., Muthusamy, Saraladevi, Lindh, Markus V., Pinhassi, Jarone, Conley, Daniel J., and Kritzberg, Emma S.

Subjects

EUTROPHICATION, WASTEWATER treatment, PLANKTON, GLOBAL warming, AQUATIC microbiology

Abstract

The Baltic Sea is the world's largest area suffering from eutrophication-driven hypoxia. Low oxygen levels are threatening its biodiversity and ecosystem functioning. The main causes for eutrophication-driven hypoxia are high nutrient loadings and global warming. Wastewater treatment plants (WWTP) contribute to eutrophication as they are important sources of nitrogen to coastal areas. Here, we evaluated the effects of wastewater treatment plant effluent inputs on Baltic Sea planktonic communities in four experiments. We tested for effects of effluent inputs on chlorophyll a content, bacterial community composition, and metabolic rates: gross primary production (GPP), net community production (NCP), community respiration (CR) and bacterial production (BP). Nitrogen-rich dissolved organic matter (DOM) inputs from effluents increased bacterial production and decreased primary production and community respiration. Nutrient amendments and seasonally variable environmental conditions lead to lower alpha-diversity and shifts in bacterial community composition (e.g. increased abundance of a few cyanobacterial populations in the summer experiment), concomitant with changes in metabolic rates. An increase in BP and decrease in CR could be caused by high lability of the DOM that can support secondary bacterial production, without an increase in respiration. Increases in bacterial production and simultaneous decreases of primary production lead to more carbon being consumed in the microbial loop, and may shift the ecosystem towards heterotrophy. [ABSTRACT FROM AUTHOR]

Published

2016

4. Are recent changes in sediment manganese sequestration in the euxinic basins of the Baltic Sea linked to the expansion of hypoxia?

Author

Lenz, C., Jilbert, T., Conley, D. J., Wolthers, M., and Slomp, C. P.

Subjects

SEDIMENTS, MANGANESE, HYPOXIA (Water), PORE water, SULFIDES

Abstract

Expanding hypoxia in the Baltic Sea over the past century has led to the development of anoxic and sulfidic (euxinic) deep basins that are only periodically ventilated by inflows of oxygenated waters from the North Sea. In this study, we investigate the potential consequences of the expanding hypoxia for manganese (Mn) burial in the Baltic Sea using a combination of pore water and sediment analyses of dated sediment cores from eight locations. Diffusive fluxes of dissolved Mn from sediments to overlying waters at oxic, hypoxic and euxinic sites are consistent with an active release of Mn from these areas. Although the present-day fluxes are significant (ranging up to ca. 240 µmol m-2 d-1), comparison to published water column data suggests that the current benthic release of Mn is small when compared to the large pool of Mn already present in the hypoxic and anoxic water column. Our results highlight two modes of Mn carbonate formation in sediments of the deep basins. In the Gotland Deep area, Mn carbonates likely form from Mn oxides that are precipitated from the water column directly following North Sea inflows. In the Landsort Deep, in contrast, Mn carbonate andMn sulfide layers appear to form independently of inflow events, and are possibly related to the much larger and continuous input of Mn oxides linked to sediment focusing. Whereas Mn-enriched sediments continue to accumulate in the Landsort Deep, this does not hold for the Gotland Deep area. Here, a recent increase in euxinia, as evident from measured bottom water sulfide concentrations and elevated sediment molybdenum (Mo), coincides with a decline in sediment Mn content. Sediment analyses also reveal that recent inflows of oxygenated water (since ca. 1995) are no longer consistently recorded as Mn carbonate layers. Our data suggest that eutrophication has not only led to a recent rise in sulfate reduction rates but also to a decline in reactive Fe input to these basins. We hypothesize that these factors have jointly led to higher sulfide availability near the sediment--water interface after inflow events. As a consequence, the Mn oxides may be reductively dissolved more rapidly than in the past and Mn carbonates may no longer form. Using a simple diagenetic model for Mn dynamics in the surface sediment, we demonstrate that an enhancement of the rate of reduction of Mn oxides is consistent with such a scenario. Our results have important implications for the use of Mn carbonate enrichments as a redox proxy in marine systems. [ABSTRACT FROM AUTHOR]

Published

2015

5. Connecting the Seas of Norden.

Author

Paasche, Øyvind, Österblom, Henrik, Neuenfeldt, Stefan, Bonsdorff, Erik, Brander, Keith, Conley, Daniel J., Durant, Joël M., Eikeset, Anne M., Goksøyr, Anders, Jónsson, Steingrímur, Kjesbu, Olav S., Kuparinen, Anna, and Stenseth, Nils Chr.

Subjects

GOVERNMENT policy on climate change, SALINITY & the environment, WINDS -- Environmental aspects, FOOD security

Abstract

The authors' discuss studies regarding the Nordic Seas and its role as an area for the integration of policy development in response to climate change. Topics include the impact of environmental stressors in the interdependent ecosystems such as salinity and shifting wind patterns, the connection between the Baltic and North seas, and the challenges faced by the global community in terms of food security and political conflicts.

Published

2015

6. Deoxygenation of the Baltic Sea during the last century.

Author

Carstensen, Jacob, Andersen, Jesper H., Gustafsson, Bo G., and Conley, Daniel J.

Subjects

PHOTOSYNTHETIC oxygen evolution, ENVIRONMENTAL disasters, DEOXYGENATION, HYPOXIA (Water), GREENHOUSE effect

Abstract

Deoxygenation is a global problem in coastal and open regions of the ocean, and has led to expanding areas of oxygen minimum zones and coastal hypoxia. The recent expansion of hypoxia in coastal ecosystems has been primarily attributed to global warming and enhanced nutrient input from land and atmosphere. The largest anthropogenically induced hypoxic area in the world is the Baltic Sea, where the relative importance of physical forcing versus eutrophication is still debated. We have analyzed water column oxygen and salinity profiles to reconstruct oxygen and stratification conditions over the last 115 y and compare the influence of both climate and anthropogenic forcing on hypoxia. We report a 10-fold increase of hypoxia in the Baltic Sea and show that this is primarily linked to increased inputs of nutrients from land, although increased respiration from higher temperatures during the last two decades has contributed to worsening oxygen conditions. Although shifts in climate and physical circulation are important factors modulating the extent of hypoxia, further nutrient reductions in the Baltic Sea will be necessary to reduce the ecosystems impacts of deoxygenation. [ABSTRACT FROM AUTHOR]

Published

2014

7. Hypoxia Sustains Cyanobacteria Blooms in the Baltic Sea.

Author

Funkey, Carolina P., Conley, Daniel J., Reuss, Nina S., Humborg, Christoph, Jilbert, Tom, and Slomp, Caroline P.

Subjects

*CYANOBACTERIAL blooms, *HYPOXIA (Water), *NITROGEN in water, *EUTROPHICATION, *NITROGEN isotopes, *HOLOCENE Epoch

Abstract

Nutrient over-enrichment is one of the classic triggering mechanisms for the occurrence of cyanobacteria blooms in aquatic ecosystems. In the Baltic Sea, cyanobacteria regularly occur in the late summer months and form nuisance accumulations in surface waters and their abundance has intensified significantly in the past 50 years attributed to human-induced eutrophication. However, the natural occurrence of cyanobacteria during the Holocene is debated. In this study, we present records of cyanobacteria pigments, water column redox proxies, and nitrogen isotopic signatures for the past ca. 8000 years from Baltic Sea sediment cores. Our results demonstrate that cyanobacteria abundance and nitrogen fixation are correlated with hypoxia occurring during three main intervals: (1) ca. 7000-4000 B.P. during the Littorina transgression, (2) ca. 1400-700 B.P. during the Medieval Climate Anomaly, and (3) from ca. 1950 A.D. to the present. Issues of preservation were investigated, and we show that organic matter and pigment profiles are not simply an artifact of preservation. These results suggest that cyanobacteria abundance is sustained during periods of hypoxia, most likely because of enhanced recycling of phosphorus in low oxygen conditions. [ABSTRACT FROM AUTHOR]

Published

2014

8. Climate dependent diatom production is preserved in biogenic Si isotope signatures.

Author

Sun, X., Andersson, P., Humborg, C., Gustafsson, B., Conley, D. J., Crill, P., Mörth, C.-M., and Semiletov, I.

Subjects

DIATOMS, ORIGIN of life, SILICON isotopes, ISOTOPE geology, ISOTOPE separation, PLANKTON -- Environmental aspects

Abstract

The aim of this study was to reconstruct diatom production in the subarctic northern tip of the Baltic Sea, Bothnian Bay, based on down-core analysis of Si isotopes in biogenic silica (BSi). Dating of the sediment showed that the samples covered the period 1820 to 2000. The sediment core record can be divided into two periods, an unperturbed period from 1820 to 1950 and a second period affected by human activities (from 1950 to 2000). This has been observed elsewhere in the Baltic Sea. The shift in the sediment core record after 1950 is likely caused by large scale damming of rivers. Diatom production was inferred from the Si isotope composition which ranged between δ30Si -0.18‰ and +0.58‰ in BSi, and assuming fractionation patterns due to the Raleigh distillation, the production was shown to be correlated with air and water temperature, which in turn were correlated with the mixed layer (ML) depth. The sedimentary record showed that the deeper ML depth observed in colder years resulted in less production of diatoms. Pelagic investigations in the 1990's have clearly shown that diatom production in the Baltic Sea is controlled by the ML depth. Especially after cold winters and deep water mixing, diatom production was limited and dissolved silicate (DSi) concentrations were not depleted in the water column after the spring bloom. Our method corroborates these findings and offers a new method to estimate diatom production over much longer periods of time in diatom dominated aquatic systems, i.e. a large part of the world's ocean and coastal seas. [ABSTRACT FROM AUTHOR]

Published

2011

9. Hypoxia Is Increasing in the Coastal Zone of the Baltic Sea.

Author

Conley, Daniel J., Carstensen, Jacob, Aigars, Juris, Axe, Philip, Bonsdorff, Erik, Eremina, Tatjana, Haahti, Britt-Marie, Humborg, Christoph, Jonsson, Per, Kotta, Jonne, Lännegren, Christer, Larsson, Ulf, Maximov, Alexey, Medina, Miguel Rodriguez, Lysiak-Pastuszak, Elzbieta, Remeikaité-Nikiené, Nijolé, Walve, Jakob, Wilhelms, Sunhild, and Zillén, Lovisa

Subjects

*HYPOXIA (Water), *MARINE eutrophication, *ECOLOGICAL impact, *ECOLOGICAL integrity, *NUTRIENT cycles, *BIOGEOCHEMICAL cycles, *MARINE ecosystem health, *MARINE ecology

Abstract

Hypoxia is a well-described phenomenon in the offshore waters of the Baltic Sea with both the spatial extent and intensity of hypoxia known to have increased due to anthropogenic eutrophication, however, an unknown amount of hypoxia is present in the coastal zone. Here we report on the widespread unprecedented occurrence of hypoxia across the coastal zone of the Baltic Sea. We have identified 115 sites that have experienced hypoxia during the period 1955-2009 increasing the global total to ca. 500 sites, with the Baltic Sea coastal zone containing over 20% of all known sites worldwide. Most sites experienced episodic hypoxia, which is a precursor to development of seasonal hypoxia. The Baltic Sea coastal zone displays an alarming trend with hypoxia steadily increasing with time since the 1950s effecting nutrient biogeochemical processes, ecosystem services, and coastal habitat. [ABSTRACT FROM AUTHOR]

Published

2011

10. Hypoxia and cyanobacterial blooms are not natural features of the Baltic Sea.

Author

Zillén, L. and Conley, D. J.

Subjects

HYPOXIA (Water), DISSOLVED oxygen in water, ANOXIC zones, CYANOBACTERIAL toxins, BACTERIAL toxins

Abstract

During the last century (1900s) industrialized forms of agriculture and human activities have caused extensive eutrophication of Baltic Sea waters. As a consequence, the Baltic Sea developed a hypoxic zone that has caused serve ecosystem distur- bance. Climate forcing has also been proposed to be responsible for the reported trends in hypoxia (<2 mg/l O2) both during the last c. 100 years and during the Medieval Period. By contrast, investigations on the degree of anthropogenic forcing on the ecosystem on long time-scales (millennial) have not been thoroughly addressed. This paper critically examines evidence for anthropogenic disturbance of the marine environment beyond the last century through the analysis of the population growth, technological development and land-use changes in the drainage area. Natural environmental changes, i.e. changes in the morphology and depths of the Baltic basin and the sills, were probably the main driver for large-scale hypoxia during the early Holocene (8000-4000 cal. yr BP). We show that hypoxia during the last two millennia has followed the general expansion and contraction trends in Europe and that human perturbations have been an important driver for hypoxia during that time. Hypoxia occurring during the Medieval Period coincides with a doubling of the population (from c. 4.6 to 9.5 million), a massive reclamation of land in both established and marginal cultivated areas and significant increases in soil nutrient release. The role of climate forcing on hypoxia in the Baltic Sea has yet to be convincingly demonstrated, although it could have contributed to sustain hypoxia through enhanced salt water inflows or through changes in hydrological inputs. In addition, cyanobacteria blooms are not natural features of the Baltic Sea as previously hypothesized, but are a consequence of enhanced phosphorus release that occurs together with hypoxia. [ABSTRACT FROM AUTHOR]

Published

2010

11. Hypoxia-Related Processes in the Baltic Sea.

Author

CONLEY, DANIEL J., BJÖRCK, SVANTE, BONSDORFF, ERIK, CARSTENSEN, JACOB, DESTOUNI, GEORGIA, GUSTAFSSON, BO G., HIETANEN, SUSANNA, KORTEKAAS, MARLOES, KUOSA, HARRI, METER, H. E. MARKUS, MÜLLER-KARULIS, BAERBEL, NORDBERG, KJELL, NORKKO, ALF, NÜRNBERG, GERTRUD, PITKÄNEN, HEIKKI, RABALAIS, NANCY N., ROSENBERG, RUTGER, SAVCHUK, OLEG P., SLOMP, CAROLINE P., and VOSS, MAREN

Subjects

*HYPOXIA (Water), *ANTHROPOGENIC effects on nature, *NUTRIENT pollution of water, *EUTROPHICATION, *NITROGEN cycle, *PHOSPHORUS cycle (Biogeochemistry), *MARINE ecology

Abstract

Hypoxia, a growing worldwide problem, has been intermittently present in the modern Baltic Sea since its formation ca. 8000 cal. yr BP. However, both the spatial extent and intensity of hypoxia have increased with anthropogenic eutrophication due to nutrient inputs. Physical processes, which control stratification and the renewal of oxygen in bottom waters, are important constraints on the formation and maintenance of hypoxia. Climate controlled inflows of saline water from the North Sea through the Danish Straits is a critical controlling factor governing the spatial extent and duration of hypoxia. Hypoxia regulates the biogeochemical cycles of both phosphorus (P) and nitrogen (N) in the water column and sediments. Significant amounts of P are currently released from sediments, an order of magnitude larger than anthropogenic inputs. The Baltic Sea is unique for coastal marine ecosystems experiencing N losses in hypoxic waters below the halocline. Although benthic communities in the Baltic Sea are naturally constrained by salinity gradients, hypoxia has resulted in habitat loss over vast areas and the elimination of benthic fauna, and has severely disrupted benthic food webs. Nutrient load reductions are needed to reduce the extent, severity, and effects of hypoxia. [ABSTRACT FROM AUTHOR]

Published

2009

12. Tackling Hypoxia in the Baltic Sea: Is Engineering a Solution?

Author

CONLEY, DANIEL J., BONSDORFF, ERIK, CARSTENSEN, JACOB, DESTOUNI, GEORGIA, GUSTAFSSON, BO G., HANSSON, LARS-ANDERS, RABALAIS, NANCY N., VOSS, MAREN, and ZILLEN, LOVISA

Subjects

*HYPOXIA (Water), *ENVIRONMENTAL engineering, *ENVIRONMENTAL remediation, *WATER quality management, *MARINE ecology

Abstract

In this article the authors discuss hypoxia in the Baltic Sea and whether engineering is a preventative solution. The authors provide an overview of hypoxia in the Baltic Sea, which is the lack of dissolved oxygen (O2) in bottom water, and the efforts taken to prevent it. They cite the frustration regarding the lack of progress in improving water quality and discuss large-scale engineered remediation projects to increase O2 in bottom waters.

Published

2009

13. Past occurrences of hypoxia in the Baltic Sea and the role of climate variability, environmental change and human impact

Author

Zillén, Lovisa, Conley, Daniel J., Andrén, Thomas, Andrén, Elinor, and Björck, Svante

Subjects

*HYPOXIA (Water), *CLIMATE change, *HYPOXEMIA, *BIOTIC communities, *FOOD chains, *FISH habitats

Abstract

Abstract: The hypoxic zone in the Baltic Sea has increased in area about four times since 1960 and widespread oxygen deficiency has severely reduced macro benthic communities below the halocline in the Baltic Proper and the Gulf of Finland, which in turn has affected food chain dynamics, fish habitats and fisheries in the entire Baltic Sea. The cause of increased hypoxia is believed to be enhanced eutrophication through increased anthropogenic input of nutrients, such as nitrogen and phosphorus. However, the spatial variability of hypoxia on long time-scales is poorly known: and so are the driving mechanisms. We review the occurrence of hypoxia in modern time (last c. 50 years), modern historical time (AD 1950–1800) and during the more distant past (the last c. 10000 years) and explore the role of climate variability, environmental change and human impact. We present a compilation of proxy records of hypoxia (laminated sediments) based on long sediment cores from the Baltic Sea. The cumulated results show that the deeper depressions of the Baltic Sea have experienced intermittent hypoxia during most of the Holocene and that regular laminations started to form c. 8500–7800 cal. yr BP ago, in association with the formation of a permanent halocline at the transition between the Early Littorina Sea and the Littorina Sea s. str. Laminated sediments were deposited during three main periods (i.e. between c. 8000–4000, 2000–800 cal. yr BP and subsequent to AD 1800) which overlap the Holocene Thermal Maximum (c. 9000–5000 cal. yr BP), the Medieval Warm Period (c. AD 750–1200) and the modern historical period (AD 1800 to present) and coincide with intervals of high surface salinity (at least during the Littorina s. str.) and high total organic carbon content. This study implies that there may be a correlation between climate variability in the past and the state of the marine environment, where milder and dryer periods with less freshwater run-off correspond to increased salinities and higher accumulation of organic carbon resulting in amplified hypoxia and enlarged distribution of laminated sediments. We suggest that hydrology changes in the drainage area on long time-scales have, as well as the inflow of saltier North Sea waters, controlled the deep oxic conditions in the Baltic Sea and that such changes have followed the general Holocene climate development in Northwest Europe. Increased hypoxia during the Medieval Warm Period also correlates with large-scale changes in land use that occurred in much of the Baltic Sea watershed during the early-medieval expansion. We suggest that hypoxia during this period in the Baltic Sea was not only caused by climate, but increased human impact was most likely an additional trigger. Large areas of the Baltic Sea have experienced intermittent hypoxic from at least AD 1900 with laminated sediments present in the Gotland Basin in the Baltic Proper since then and up to present time. This period coincides with the industrial revolution in Northwestern Europe which started around AD 1850, when population grew, cutting of drainage ditches intensified, and agricultural and forest industry expanded extensively. [Copyright &y& Elsevier]

Published

2008

14. Past, present and future state of the biogeochemical Si cycle in the Baltic Sea

Author

Conley, Daniel J., Humborg, Christoph, Smedberg, Erik, Rahm, Lars, Papush, Liana, Danielsson, Åsa, Clarke, Annemarie, Pastuszak, Marianna, Aigars, Juris, Ciuffa, Daniele, and Mörth, Carl-Magnus

Subjects

*BIOGEOCHEMICAL cycles, *SILICA content of seawater, *AQUATIC ecology, *BIOTIC communities, *EUTROPHICATION, *SEDIMENTATION & deposition, *MATHEMATICAL models

Abstract

Abstract: The Baltic Sea is one of many aquatic ecosystems that show long-term declines in dissolved silicate (DSi) concentrations due to anthropogenic alteration of the biogeochemical Si cycle. Reductions in DSi in aquatic ecosystems have been coupled to hydrological regulation reducing inputs, but also with eutrophication, although the relative significance of both processes remains unknown for the observed reductions in DSi concentrations. Here we combine present and historical data on water column DSi concentrations, together with estimates of present river DSi loads to the Baltic, the load prior to damming together with estimates of the long-term accumulation of BSi in sediments. In addition, a model has been used to evaluate the past, present and future state of the biogeochemical Si cycle in the Baltic Sea. The present day DSi load to the Baltic Sea is 855 ktons y−1. Hydrological regulation and eutrophication of inland waters can account for a reduction of 420 ktons y−1 less riverine DSi entering the Baltic Sea today. Using published data on basin-wide accumulation rates we estimate that 1074 ktons y−1 of biogenic silica (BSi) is accumulating in the sediments, which is 36% higher than earlier estimates from the literature (791 ktons y−1). The difference is largely due to the high reported sedimentation rates in the Bothnian Sea and the Bothnian Bay. Using river DSi loads and estimated BSi accumulation, our model was not able to estimate water column DSi concentrations as burial estimates exceeded DSi inputs. The model was then used to estimate the BSi burial from measured DSi concentrations and DSi load. The model estimate for the total burial of BSi in all three basins was 620 ktons y−1, 74% less than estimated from sedimentation rates and sediment BSi concentrations. The model predicted 20% less BSi accumulation in the Baltic Proper and 10% less in the Bothnian Bay than estimated, but with significantly less BSi accumulation in the Bothnian Sea by a factor of 3. The model suggests there is an overestimation of basin-wide sedimentation rates in the Bothnian Bay and the Bothnian Sea. In the Baltic Proper, modelling shows that historical DSi concentrations were 2.6 times higher at the turn of the last century (ca. 1900) than at present. Although the DSi decrease has leveled out and at present there are only restricted areas of the Baltic Sea with limiting DSi concentrations, further declines in DSi concentrations will lead to widespread DSi limitation of diatoms with severe implications for the food web. [Copyright &y& Elsevier]

Published

2008

15. Silicon dynamics in the Oder estuary, Baltic Sea

Author

Pastuszak, Marianna, Conley, Daniel J., Humborg, Christoph, Witek, Zbigniew, and Sitek, Stanisław

Subjects

*SILICA content of seawater, *SEDIMENTATION & deposition, *MAXIMA & minima, *SEASONS

Abstract

Abstract: Studies on dissolved silicate (DSi) and biogenic silica (BSi) dynamics were carried out in the Oder estuary, Baltic Sea in 2000–2005. The Oder estuary proved to be an important component of the Oder River–Baltic Sea continuum where very intensive seasonal DSi uptake during spring and autumn, but also BSi regeneration during summer take place. Owing to the regeneration process annual DSi patterns in the river and the estuary distinctly differed; the annual patterns of DSi in the estuary showed two maxima and two minima in contrast to one maximum- and one minimum-pattern in the Oder River. DSi concentrations in the river and in the estuary were highest in winter (200–250 μmol dm−3) and lowest (often less than 1 μmol dm−3) in spring, concomitant with diatom growth; such low values are known to be limiting for new diatom growth. Secondary DSi summer peaks at the estuary exit exceeded 100 μmol dm−3, and these maxima were followed by autumn minima coinciding with the autumn diatom bloom. Seasonal peaks in BSi concentrations (ca. 100 μmol dm−3) occurred during the spring diatom bloom in the Oder River. Mass balance calculations of DSi and BSi showed that DSi+BSi import to the estuary over a two year period was 103.2 kt and that can be compared with the DSi export of 98.5 kt. The difference between these numbers gives room for ca. 2.5 kt BSi to be annually exported to the Baltic Sea. Sediment cores studies point to BSi annual accumulation on the level of 2.5 kt BSi. BSi import to the estuary is on the level of ca. 10.5 kt, thus ca. 5 kt of BSi is annually converted into the DSi, increasing the pool of DSi that leaves the system. BSi concentrations being ca. 2 times higher at the estuary entrance than at its exit remain in a good agreement with the DSi and BSi budgeting presented in the paper. [Copyright &y& Elsevier]

Published

2008

16. Internal Ecosystem Feedbacks Enhance Nitrogen-fixing Cyanobacteria Blooms and Complicate Management in the Baltic Sea.

Author

Vahtera, Emil, Conley, Daniel J., Gustafsson, Bo G., Kuosa, Harri, Pitkänen, Heikki, Savchuk, Oleg P., Tamminen, Timo, Viitasalo, Markku, Voss, Maren, Wasmund, Norbert, and Wulff, Fredrik

Subjects

*CYANOBACTERIA, *CYANOBACTERIAL blooms, *PHOSPHORUS, *NITROGEN, *EUTROPHICATION, *NITROGEN fixation, *HYPOXIA (Water)

Abstract

Eutrophication of the Baltic Sea has potentially increased the frequency and magnitude of cyanobacteria blooms. Eutrophication leads to increased sedimentation of organic material, increasing the extent of anoxic bottoms and subsequently increasing the internal phosphorus loading. In addition, the hypoxic water volume displays a negative relationship with the total dissolved inorganic nitrogen pool, suggesting greater overall nitrogen removal with increased hypoxia. Enhanced internal loading of phosphorus and the removal of dissolved inorganic nitrogen leads to lower nitrogen to phosphorus ratios, which are one of the main factors promoting nitrogen-fixing cyanobacteria blooms. Because cyanobacteria blooms in the open waters of the Baltic Sea seem to be strongly regulated by internal processes, the effects of external nutrient reductions are scale-dependent. During longer time scales, reductions in external phosphorus load may reduce cyanobacteria blooms; however, on shorter time scales the internal phosphorus loading can counteract external phosphorus reductions. The coupled processes inducing internal loading, nitrogen removal, and the prevalence of nitrogen-fixing cyanobacteria can qualitatively be described as a potentially self-sustaining "vicious circle." To effectively reduce cyanobacteria blooms and overall signs of eutrophication, reductions in both nitrogen and phosphorus external loads appear essential. [ABSTRACT FROM AUTHOR]

Published

2007

17. Hypoxia in the Baltic Sea and Basin-Scale Changes in Phosphorus Biogeochemistry.

Author

Conley, Daniel J., Humborg, Christoph, Rahm, Lars, Savchuk, Oleg P., and Wulff, Fredrik

Subjects

*HYPOXIA (Water), *BIOGEOCHEMISTRY, *PHOSPHORUS

Abstract

Analyzes the hypoxia in the Baltic Sea and basin-scale changes in phosphorus biogeochemistry. Oxygen in bottom waters; Phosphorus biogeochemistry; Importance of phosphorus in eutrophication.

Published

2002

18. Ecological hypotheses for a historical reconstruction of upper trophic level biomass in the Baltic Sea and Skagerrak.

Author

MacKenzie, Brian R., Alheit, Jürgen, Conley, Daniel J., Holm, Poul, and Kinze, Carl Christian

Subjects

FISH populations, MARINE mammal populations

Abstract

Summarizes how fluctuations in fish and marine mammal populations in the Baltic Sea and Skagerrak since the 1500s. Climatic influences; Eutrophication trends; Potential contribution of historical research to Baltid cod biology; Effects of marine mammal predation on cod abundance; Effects of environmental factors on cod abundance.

Published

2002

19. Silicon retention in river basins: far-reaching effects on biogeochemistry and aquatic food webs in coastal marine environments

Author

Ittekkot, Venugopalan, Humborg, Christoph, Conley, Daniel J., Wulff, Fredrik, Cociasu, Adriana, and Rahm, Lars

Subjects

BIOGEOCHEMISTRY

Published

2000

20. Biogeochemical and environmental drivers of coastal hypoxia.

Author

Caballero-Alfonso, Angela M., Carstensen, Jacob, and Conley, Daniel J.

Subjects

*HYPOXIA (Water), *BIOGEOCHEMICAL cycles, *DISSOLVED oxygen in water, *OCEAN bottom, *OCEAN temperature

Abstract

Recent reports have demonstrated that hypoxia is widespread in the coastal zone of the Baltic Sea. Here we evaluate the long-term trends of dissolved oxygen in bottom waters and of the drivers of coastal hypoxia. Eleven of the 33 sites evaluated had increasing trends of bottom water dissolved oxygen, but only the Stockholm Archipelago presents a consistent positive increasing trend in time. The vast majority of sites continue to worsen, especially along the Danish and Finnish coasts, in spite of remediation efforts to reduce nutrients. Surface temperatures were relatively comparable across the entire coastal Baltic Sea, whereas bottom water temperatures varied more strongly among sites, most likely due to differences in mixing (or stratification) and water exchange with the open Baltic Sea. Nutrient concentrations varied by factors 2–3 with highest levels at sites with restricted water exchange and higher land based nutrient loading. None of the sites were permanently stratified during the summer seasonal window although most of the sites were stratified more than half of the time. The frequency of hypoxia was also quite variable with sites in Gulf of Bothnia almost never experiencing hypoxia to enclosed sites with more than 50% chance of hypoxia. There are many factors governing hypoxia and the complexity of interacting processes in the coastal zone makes it difficult to identify specific causes. Our results demonstrate that managing nutrients can create positive feedbacks for oxygen recovery to occur. In the absence of nutrient reductions, the recovery from hypoxia in coastal marine ecosystems is unlikely. [ABSTRACT FROM AUTHOR]

Published

2015

21. Diatom stratigraphy and long-term dissolved silica concentrations in the Baltic Sea

Author

Olli, Kalle, Clarke, Annemarie, Danielsson, Åsa, Aigars, Juris, Conley, Daniel J., and Tamminen, Timo

Subjects

*SILICA content of seawater, *DIATOMS, *EUTROPHICATION, *PLANKTON blooms, *SEDIMENTATION & deposition, *THALASSIOSIRA, *BIOMASS

Abstract

Abstract: In many parts of the world coastal waters with anthropogenic eutrophication have experienced a gradual depletion of dissolved silica (DSi) stocks. This could put pressure on spring bloom diatom populations, e.g. by limiting the intensity of blooms or by causing shifts in species composition. In addition, eutrophication driven enhanced diatom growth is responsible for the redistribution of DSi from the water phase to the sediments, and changes in the growth conditions may be reflected in the sediment diatom stratigraphy. To test for changes in diatom communities we have analyzed four sediment cores from the Baltic Sea covering approximately the last 100 years. The sediment cores originate from the western Gulf of Finland, the Kattegat, the Baltic Proper and the Gulf of Riga. Three out of the four cores reveal only minor changes in composition of diatom assemblages, while the Gulf of Riga core contains major changes, occurring after the second World War. This area is set apart from the other Baltic Sea basins by a high frequency of low after spring bloom DSi concentrations (<2 µmol L−1) during a relatively well defined time period from 1991–1998. In 1991 to 1993 a rapid decline of DSi spring concentrations and winter stocks (down to 5 µmol L−1) in the Gulf was preceded by exceptionally intense diatom spring blooms dominated by the heavily silicified species Thalassiosira baltica (1991–1992; up to 5.5 mg ww L−1). T. baltica has been the principal spring bloom diatom in the Gulf of Riga since records began in 1975. DSi consumption and biomass yield experiments with cultured T. baltica suggest that intense blooms can potentially exhaust the DSi stock of the water column and exceed the annual Si dissolution in the Gulf of Riga. The phytoplankton time series reveals another exceptional T. baltica bloom period in 1981–1983 (up to 8 mg L−1), which, however, took place before the regular DSi measurements. These periods may be reflected in the conspicuous accumulation of T. baltica frustules in the sediment core corresponding to ca. 1975–1985. [Copyright &y& Elsevier]

Published

2008