The impact of meltwater discharge from the Greenland ice sheet on the Atlantic nutrient supply to the northwest European shelf

Mathis, Moritz; Mikolajewicz, Uwe

doi:10.5194/os-16-167-2020

Cited by 7 publications

(7 citation statements)

References 102 publications

(154 reference statements)

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“…Second, however, Laufkötter et al (2013) and Matsumoto et al (2010) used a fully coupled Earth System Model that accounts for feedbacks between atmospheric and oceanic processes while our modelling framework relies on a prescribed atmospheric state. Third, the global response of hydrodynamical and biogeochemical processes to changes in the physical climate has been shown to strongly vary from one model to the other (Bopp et al, 2013;Kwiatkowski et al, 2017Kwiatkowski et al, , 2020Laufkötter et al, 2015;Mathis & Mikolajewicz, 2020;Matsumoto et al, 2010). Thus, the trend in the marine NPP is also strongly affected by the different architectures and formulations for hydrodynamical and biogeochemical processes in different models.…”

Section: Role Of Changes In the Physical Climate For Oceanic Carbon Cyclingmentioning

confidence: 99%

“…Local changes in ocean circulation seem to be of even larger importance in the coastal ocean, where hydrodynamical circulation While decadal variability of the ocean system currently prevents definite conclusions regarding the impacts of climate-induced changes on the biological productivity from observations alone, modelling studies have addressed these perturbations at global (Bopp et al, 2013;Laufkötter et al, 2013Laufkötter et al, , 2015Matsumoto et al, 2010) and regional scales (Fennel et al, 2006;Frischknecht et al, 2018;Holt et al, 2016Holt et al, , 2018Mathis et al, 2019). In Laufkötter et al (2013) to changes in the physical climate has been shown to strongly vary from one model to the other (Bopp et al, 2013;Kwiatkowski et al, 2017Kwiatkowski et al, , 2020Laufkötter et al, 2015;Mathis & Mikolajewicz, 2020;Matsumoto et al, 2010). Thus, the trend in the marine NPP is also strongly affected by the different architectures and formulations for hydrodynamical and biogeochemical processes in different models.…”

Section: Role Of Changes In the Physical Climate For Oceanic Carbon C...mentioning

confidence: 99%

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Historical increases in land‐derived nutrient inputs may alleviate effects of a changing physical climate on the oceanic carbon cycle

Lacroix

Ilyina

Mathis³

et al. 2021

Global Change Biology

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Section: Role Of Changes In the Physical Climate For Oceanic Carbon Cyclingmentioning

confidence: 99%

Section: Role Of Changes In the Physical Climate For Oceanic Carbon C...mentioning

confidence: 99%

Historical increases in land‐derived nutrient inputs may alleviate effects of a changing physical climate on the oceanic carbon cycle

Lacroix

Ilyina

Mathis³

et al. 2021

Global Change Biology

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“…The ensemble simulation dataset represents changes in ocean density and currents as well as meteorological conditions including atmospheric water transport due to the enhanced radiative forcing under climate change. The ensemble is created by starting the global model from different historical states of the years 1950-1959 of three previous simulations with the same model system (Mathis and Mikolajewicz, 2020). For the downscaling of the global simulations, its 6-hourly outputs serve as a forcing for the MPIOM-REMO regional climate modelling framework, which, in turn, provides the boundary forcing for the SCHISM simulations analysed in this study.…”

Section: Global Climate Scenariosmentioning

confidence: 99%

A framework for estuarine future sea-level scenarios: Response of the industrialised Elbe estuary to projected mean sea level rise and internal variability

et al. 2023

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In this study, we apply probabilistic estimates of mean sea level (MSL) rise and a sub-set of regional climate model ensemble simulations to force a numerical model of the southern North Sea, downscaling projected sea level variability to the Elbe estuary that serves as a prototype for an industrialised meso-tidal estuary. The specific forcing combination enables a localised projection of future estuarine hydrodynamics accounting for the spread of projected global sea level rise and the spread of the regional climate projection due to internal variability. Under the applied high-emission scenario, the Elbe estuary shows high decadal rates of mean water level (MWL) rise beyond 19 mm y-1, increase in the tidal range of up to 14 mm y-1 and increase in extreme water levels of up to 18 mm y-1. The bandwidth of the estuarine response is also high. For example, the range of average monthly extreme water levels is up to 0.57 m due to the spread of projected global sea level rise, up to 0.58 m due to internal variability whereas seasonal range attains 1.99 m locally. In the lower estuary, the spread of projected global sea level rise dominates over internal variability. Internal variability, represented by ensemble spread, notably impacts the range of estuarine water levels and tidal current asymmetry in the shallow upper estuary. This area demonstrates large seasonal fluctuations of MWLs, the M2 tidal amplitude and monthly extreme water levels. On the monthly and inter-annual time scales, the MWL and M2 amplitude reveal opposite trends, indicative of a locally non-linear response to the decadal MSL rise enforced at the open boundary. Overall, imposed by the climate projections decadal change and MSL rise enhance the horizontal currents and turbulent diffusivities whereas internal variability locally mitigates sea level rise–driven changes in the water column. This work establishes a framework for providing consistent regionalised scenario-based climate change projections for the estuarine environment to support sustainable adaptation development.

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“…Each member of this ensemble covers the period 1950-2005 with the corresponding historical atmospheric pCO2 and their continuation from 2006 to 2099 under the RCP8.5 emission scenario. Members differ from each other only due to different initial states, taken from historical initial states of the years 1950-1959 of three previous simulations with the same model system, which were analyzed by Mathis and Mikolajewicz (2020). An additional control run with constant pre-industrial atmospheric pCO2 (PI) simulated the full period 1950-2099 to obtain information about model-internal variability and possible drifts.…”

Section: Introductionmentioning

confidence: 99%

RCP8.5-projected changes in German Bight storm surge characteristics from regionalized ensemble simulations for the end of the twenty-first century

Mayer¹,

Mathis²,

Mikolajewicz³

et al. 2022

Front. Clim.

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This study investigates climate-induced changes in height, frequency and duration of storm surges in the German Bight. The regionally coupled climate model system MPIOM-REMO with a focus on the North Sea has been utilized to dynamically downscale 30 members of the global climate model system MPI-ESM1.1-LR for the historical period 1950–2005 and a continuation until 2099 with the RCP8.5 scenario. Results of all members have been collected into the historical (1970–1999) and the rcp85 (2070–2099) data pools amounting to 900 years of the corresponding climate state. The global mean sea level rise was not considered. Nevertheless, the mean ensemble German Bight SSH trend amounts to about 13 ± 1 cm/century (PI control: 3 cm/century) due to adaptation of the ocean circulation to the changing climatic conditions. Storm surges were defined as SSH above mean high tidal water plus 1.5, 2.5, 3.5 m for “regular”, heavy, extreme storm surges, and then clustered to events. Our simulated storm surge events show a clear location-dependent increase in frequency (6–11%), median duration (4–24%), and average duration (9–20%) in the German Bight. Only along the central German Bight coast (Cuxhaven), longer lasting events gain more relevance. Heavy storm surge events show also a strong increase in frequency (7–34%) and average duration (10–22%). Maximum sea levels during storm events increase strongest and most significant along the northern German Bight and Danish coasts with more than 30 cm/century for the 60-year return period at Hörnum and 10–15 cm/century for shorter return periods. Levels of return periods shorter than a few years significantly increase everywhere along the southern German Bight coasts (around 5 cm/century for the 2-year return period). Highest SSH maxima do not change, and consequently, extreme storm surge events show hardly any response to climate change. Furthermore, our results indicate a shift of seasonality from the last to the first quarter of a year. As the main driver for the encountered alteration of German Bight storm surge characteristics, we identified a change in wind conditions with a pronounced increase of frequency of strong westerly winds.

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The impact of meltwater discharge from the Greenland ice sheet on the Atlantic nutrient supply to the northwest European shelf

Cited by 7 publications

References 102 publications

Historical increases in land‐derived nutrient inputs may alleviate effects of a changing physical climate on the oceanic carbon cycle

Historical increases in land‐derived nutrient inputs may alleviate effects of a changing physical climate on the oceanic carbon cycle

A framework for estuarine future sea-level scenarios: Response of the industrialised Elbe estuary to projected mean sea level rise and internal variability

RCP8.5-projected changes in German Bight storm surge characteristics from regionalized ensemble simulations for the end of the twenty-first century

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