Environmental Impacts—Marine Biogeochemistry

Schneider, Bernd; Eilola, Kari; Lukkari, Kaarina; Müller‐Karulis, Bärbel; Neumann, Thomas

doi:10.1007/978-3-319-16006-1_18

Cited by 19 publications

(10 citation statements)

References 170 publications

(193 reference statements)

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“…Pelagic primary production can however contribute to surface water A T , when the organic matter is exported. With respect to alkalinity trends in the Baltic Sea surface water, it is reasonable to assume that nitrate based primary production and thus the A T contribution increased along with nutrient inputs that peaked around 1980 (Gustafsson et al ; Schneider et al ). However, recent modelling studies suggest that the previously increasing nitrogen uptake by phytoplankton levelled off around 1990 (Gustafsson et al ).…”

Section: Discussionmentioning

confidence: 99%

“…This implies that a reliable acidification estimate cannot solely be based on the atmospheric pCO 2 evolution. Previous studies indeed suggested that the alkalinity in the eastern Gotland Sea increased by around 100 µmol kg −1 (∼6%) from 1930 to 2010 (Schneider et al ). Extensive A T measurements were performed in the Baltic Sea region with investigations dating back to the early 20 th century (Buch ; Hjalmarsson et al ).…”

Section: Introductionmentioning

confidence: 91%

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Long-term alkalinity trends in the Baltic Sea and their implications for CO₂ -induced acidification

2016

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Anthropogenic CO 2 emissions currently decrease open ocean pH, but on multi-millennial time scales intensified continental weathering is expected to contribute to increasing oceanic alkalinity (A T ) and thus mitigate the acidification signal. The Baltic Sea is an ideal study site for such A T dynamics, due to its direct link to terrestrial processes, short water residence time and long history of A T measurements dating back to the early 20 th century. We compiled an extensive A T data set that revealed the highest data quality and coverage for the past two decades. Within that period, surface water A T levels increased throughout the Baltic Sea. The rates of change were highest in the low-saline, northern areas and decreased gradually toward constant levels in the North Sea. The A T increase observed in the Central Baltic Sea (13.4 mmol kg 21 yr 21 ) and the Gulf of Bothnia (17 mmol kg 21 yr 21 ) has compensated CO 2 -induced acidification by almost 50% and 100%, respectively. Further, the A T trends enhanced the CO 2 storage capacity and stabilized the CaCO 3 saturation state of the Baltic Sea over the past two decades. We discuss the attribution of the A T trends to potential changes in precipitation patterns, continental weathering driven by acidic rain and increasing atmospheric CO 2 , agricultural liming and internal A T sources.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 91%

Long-term alkalinity trends in the Baltic Sea and their implications for CO₂ -induced acidification

2016

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“…All treatments were superimposed on the natural fluctuations of all environmental variables. The elevated levels of both factors were chosen according to climate change predictions for shallow coastal Baltic habitats over the next 100 years (Elken et al ; Schneider et al ).…”

Section: Materials and Proceduresmentioning

confidence: 99%

Model simulation of seasonal growth of Fucus vesiculosus in its benthic community

Graiff

Karsten

Radtke

et al. 2020

Limnology & Ocean Methods

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Numerical models are a suitable tool to quantify impacts of predicted climate change on complex ecosystems but are rarely used to study effects on benthic macroalgal communities. Fucus vesiculosus L. is a habitat‐forming macroalga in the Baltic Sea and alarming shifts from the perennial Fucus community to annual filamentous algae are reported. We developed a box model able to simulate the seasonal growth of the Baltic Fucus–grazer–epiphyte system. This required the implementation of two state variables for Fucus biomass in units of carbon (C) and nitrogen (N). Model equations describe relevant physiological and ecological processes, such as storage of C and N assimilates by Fucus, shading effects of epiphytes or grazing by herbivores on both Fucus and epiphytes, but with species‐specific rates and preferences. Parametrizations of the model equations and required initial conditions were based on measured parameters and process rates in the near‐natural Kiel Outdoor Benthocosm (KOB) experiments during the Biological Impacts of Ocean Acidification project. To validate the model, we compared simulation results with observations in the KOB experiment that lasted from April 2013 until March 2014 under ambient and climate‐change scenarios, that is, increased atmospheric temperature and partial pressure of carbon dioxide. The model reproduced the magnitude and seasonal cycles of Fucus growth and other processes in the KOBs over 1 yr under different scenarios. Now having established the Fucus model, it will be possible to better highlight the actual threat of climate change to the Fucus community in the shallow nearshore waters of the Baltic Sea.

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“…Due to anthropogenic global change, ocean warming and acidification may singly or interactively affect photophysiological performance of Fucus during the different seasons. Fucus was exposed to single and combined treatments of elevated seawater temperature ( + 5 • C) and pCO 2 (1100 ppm) in all four seasons as predicted for shallow coastal Baltic habitats for the year 2100 (Elken et al, 2015;Schneider et al, 2015;Müller et al, 2016). These scenarios, including natural fluctuations forced by diurnal and seasonal changes, atmospheric and hydrographic conditions, were simulated using benthic mesocosms [Kiel Outdoor Benthocosms (KOBs), Wahl et al, 2015a].…”

Section: Introductionmentioning

confidence: 99%

Seasonal Photophysiological Performance of Adult Western Baltic Fucus vesiculosus (Phaeophyceae) Under Ocean Warming and Acidification

et al. 2021

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Shallow coastal marine ecosystems are exposed to intensive warming events in the last decade, threatening keystone macroalgal species such as the bladder wrack (Fucus vesiculosus, Phaeophyceae) in the Baltic Sea. Herein, we experimentally tested in four consecutive benthic mesocosm experiments, if the single and combined impact of elevated seawater temperature (Δ + 5°C) and pCO2 (1100 ppm) under natural irradiance conditions seasonally affected the photophysiological performance (i.e., oxygen production, in vivo chlorophyll a fluorescence, energy dissipation pathways and chlorophyll concentration) of Baltic Sea Fucus. Photosynthesis was highest in spring/early summer when water temperature and solar irradiance increases naturally, and was lowest in winter (December to January/February). Temperature had a stronger effect than pCO2 on photosynthetic performance of Fucus in all seasons. In contrast to the expectation that warmer winter conditions might be beneficial, elevated temperature conditions and sub-optimal low winter light conditions decreased photophysiological performance of Fucus. In summer, western Baltic Sea Fucus already lives close to its upper thermal tolerance limit and future warming of the Baltic Sea during summer may probably become deleterious for this species. However, our results indicate that over most of the year a combination of future ocean warming and increased pCO2 will have slightly positive effects for Fucus photophysiological performance.

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Environmental Impacts—Marine Biogeochemistry

Cited by 19 publications

References 170 publications

Long-term alkalinity trends in the Baltic Sea and their implications for CO₂ -induced acidification

Long-term alkalinity trends in the Baltic Sea and their implications for CO₂ -induced acidification

Model simulation of seasonal growth of Fucus vesiculosus in its benthic community

Seasonal Photophysiological Performance of Adult Western Baltic Fucus vesiculosus (Phaeophyceae) Under Ocean Warming and Acidification

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Environmental Impacts—Marine Biogeochemistry

Cited by 19 publications

References 170 publications

Long-term alkalinity trends in the Baltic Sea and their implications for CO2 -induced acidification

Long-term alkalinity trends in the Baltic Sea and their implications for CO2 -induced acidification

Model simulation of seasonal growth of Fucus vesiculosus in its benthic community

Seasonal Photophysiological Performance of Adult Western Baltic Fucus vesiculosus (Phaeophyceae) Under Ocean Warming and Acidification

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Long-term alkalinity trends in the Baltic Sea and their implications for CO₂ -induced acidification

Long-term alkalinity trends in the Baltic Sea and their implications for CO₂ -induced acidification