The influence of tides on the marine carbonate chemistry of  a coastal polynya in the south-eastern Weddell Sea

Droste, Elise; Hoppema, Mario; González‐Dávila, Melchor; Santana-Casiano, J. Magdalena; Queste, Bastien Y.; Dall’Olmo, Giorgio; Venables, Hugh J.; Rohardt, Gerd; Ossebaar, Sharyn; Schuller, Daniel; Trace-Kleeberg, Sunke; Bakker, D. C. E.

doi:10.5194/os-18-1293-2022

Cited by 4 publications

(3 citation statements)

References 65 publications

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“…For example, frontal regions are associated with enhanced biological activity, leading to variability in uptake and remineralization rates of nutrients across smaller hydrographic scales (Eveleth et al, 2014). Tidal currents in regions where horizontal gradients of water masses exist, e.g., between Yermak Plateau and Fram Strait, can also lead to rapid change in the nutrient and carbonate system of the surface ocean on semidiurnal and diurnal time scales and cause polar waters to switch between a CO 2 sink and source multiple times a day (Skogseth et al, 2013;Llanillo et al, 2019;Droste et al, 2022).…”

Section: Nutrient and Carbonate System Dynamicsmentioning

confidence: 99%

The Eurasian Arctic Ocean along the MOSAiC drift in 2019-2020: An interdisciplinary perspective on physical properties and processes

Schulz,

Koenig,

Muilwijk

et al. 2024

Preprint

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The Multidisciplinary drifting Observatory for the Study of the Arctic Climate (MOSAiC, 2019/2020), a year-long drift with the Arctic sea ice, has provided the scientific community with an unprecedented, multidisciplinary dataset from the Eurasian Arctic Ocean, covering high atmosphere to deep ocean across all seasons. However, the heterogeneity of data and the superposition of spatial and temporal variability, intrinsic to a drift campaign, complicate the interpretation of observations. In this study, we compile a quality-controlled hydrographic dataset with best spatio-temporal coverage and derive core parameters, including the mixed layer depth, heat fluxes over key layers, and friction velocity. We provide a comprehensive and accessible overview of the ocean conditions encountered along the MOSAiC drift, discuss their interdisciplinary implications, and compare common ocean climatologies to these new data. Our results indicate that - for the most parts - ocean variability was dominated by regional, rather than seasonal signals, with potentially strong implications for ocean biogeochemistry, ecology, sea ice, and even atmospheric conditions. Near-surface ocean properties are strongly influenced by the relative position of sampling within or outside the river-water influenced Transpolar Drift, and seasonal warming and meltwater input. Ventilation down to the Atlantic Water layer in the Nansen Basin allows for a stronger connectivity to both sea ice and surface ocean, including elevated upward heat fluxes. The Yermak Plateau and Fram Strait region are characterized by variable conditions, strong ocean currents, a stronger influence of Atlantic Water, and substantial lateral gradients in surface water properties in frontal regions. Together with the presented results and core parameters, we offer context for interdisciplinary research, fostering an improved understanding of the complex, coupled Arctic System.

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Section: Nutrient and Carbonate System Dynamicsmentioning

confidence: 99%

The Eurasian Arctic Ocean along the MOSAiC drift in 2019-2020: An interdisciplinary perspective on physical properties and processes

Schulz,

Koenig,

Muilwijk

et al. 2024

Preprint

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“…In addition, the consumption of contaminated salt can accumulate health problems (Bai et al, 2015;Manzoor et al, 2018;Baeyens et al, 2019). Hence, seawater sources used to obtain natural rich minerals sea salt should be free from contaminants and also collected during high tide condition due to the largest ion contents (Droste et al, 2022). The seawater source used for raw material of rich mineral sea salt production is located in Camplong District, Sampang Regency, Madura (7°13'08.8" South Latitude and 113°21'05.8" East Longitude).…”

Section: Introductionmentioning

confidence: 99%

Analysis of Chemical Contents in Raw Material of Rich Minerals Sea Salt

Afnani¹,

Pratiwi

Effendy³

et al. 2022

JKR

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The mineral content of seawater is a natural raw material to produce rich mineral sea salt. Rich mineral sea salt is a consumption salt with a NaCl content of <50% used to live a low sodium diet for a healthy lifestyle. In general, traditional sea salt was produced with the multistage evaporation method to obtain a NaCl content of ≥ 94.7%, whereas the production of rich mineral sea salt uses a total evaporation method and then removes the salt flower at a certain concentration to get low sodium chlorine and contain other natural minerals. This study aims to analyze the chemical content of the raw material of rich mineral sea salt. The location of seawater used as raw material for rich mineral sea salt is Camplong District, Sampang Regency. Samples were obtained from sea level with a distance of ± 400 m from the coastline and carried out during high tide conditions. The chemical analysis of seawater samples consists of Na, Mg, Ca, K, Fe, Cl− dan SO42−. The analysis method is based on the Indonesian National Standard of environmental quality test. The results of the major mineral analysis showed that the largest mineral content of seawater was calcium (Ca2+) at 492.350±10.395 mg/L and Sodium (Na+) at 482,000±1.979 mg/L. In contrast, the smallest mineral content is iron mineral (Fe2+) of < 0.08 mg/L. These results will be used for preliminary data before producing naturally rich mineral sea salt.

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“…While daily-averaged model output is typically used in studies assessing changes in extreme environmental conditions, our understanding of variability on daily and sub-daily time scales and its impacts on global ecosystems remains incomplete (Gruber et al, 2021). Based on regional hydrographic, glider, and mooring observations, we know that substantial short-term variability in ecosystem stressors is caused by, e.g., the diurnal cycle (Torres et al, 2021), tides (Droste et al, 2022), or ocean weather (Nicholson et al, 2022). As a result, such variability is possibly a key factor in determining an organism's resilience to environmental change (Helmuth et al, 2014;Kapsenberg and Cyronak, 2019).…”

mentioning

confidence: 99%

Using synthetic float capabilities in E3SMv2 to assess spatio-temporal variability in ocean physics and biogeochemistry

Nissen,

Lovenduski,

Maltrud

et al. 2024

Preprint

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Abstract. Since their advent over two decades ago, autonomous Argo floats have revolutionized the field of oceanography, and more recently, the addition of biogeochemical and biological sensors to these floats has greatly improved our understanding of carbon, nutrient, and oxygen cycling in the ocean. While Argo floats offer unprecedented horizontal, vertical, and temporal coverage of the global ocean, uncertainties remain about whether Argo sampling frequency and density capture the true spatio-temporal variability of physical, biogeochemical, and biological properties. As the true distributions of, e.g., temperature or oxygen are unknown, these uncertainties remain difficult to address with Argo floats alone. Numerical models with synthetic observing systems offer one potential avenue to address these uncertainties. Here, we implement synthetic biogeochemical Argo floats into the Energy Exascale Earth System Model version 2 (E3SMv2). Since the synthetic floats sample the model fields at model run time, the end-user defines the sampling protocol ahead of any model simulation, including the number and distribution of synthetic floats to be deployed, their sampling frequency, and the prognostic or diagnostic model fields to be sampled. Using a six-year proof-of-concept simulation, we illustrate the utility of the synthetic floats in different case studies. In particular, we quantify the impact of i) sampling density on the float-derived detection of deep-ocean change in temperature or oxygen and on float-derived estimates of phytoplankton phenology, ii) sampling frequency and sea-ice cover on float trajectory lengths and hence float-derived estimates of current velocities, and iii) short-term variability in ecosystem stressors on estimates of seasonal variability.

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The influence of tides on the marine carbonate chemistry of a coastal polynya in the south-eastern Weddell Sea

Cited by 4 publications

References 65 publications

The Eurasian Arctic Ocean along the MOSAiC drift in 2019-2020: An interdisciplinary perspective on physical properties and processes

The Eurasian Arctic Ocean along the MOSAiC drift in 2019-2020: An interdisciplinary perspective on physical properties and processes

Analysis of Chemical Contents in Raw Material of Rich Minerals Sea Salt

Using synthetic float capabilities in E3SMv2 to assess spatio-temporal variability in ocean physics and biogeochemistry

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