Long-term alkalinity trends in the Baltic Sea and their implications for CO<sub>2</sub>
-induced acidification

Müller, Jens Daniel; Schneider, Bernd; Rehder, Gregor

doi:10.1002/lno.10349

Cited by 96 publications

(119 citation statements)

References 62 publications

(104 reference statements)

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“…There, an increase in A T of 3.4 µmol kg −1 yr −1 was observed from 1995 to 2014 (mean salinity = 7). In contrast to Point B, the increase in Baltic Sea A T was not noticeable at salinity > 30 (Müller et al, 2016).…”

Section: Discussioncontrasting

confidence: 56%

“…Positive trends in river A T have been documented in North America and occur via a number of processes including (1) the interplay of rainfall and land use (Raymond and Cole, 2003), (2) anthropogenic limestone addition used to enhance agricultural soil pH (Oh and Raymond, 2006;Stets et al, 2014) and freshwater pH (Clair and Hindar, 2005), and (3) potentially indirect effects of anthropogenic CO 2 on groundwater CO 2 acidification and weathering (Macpherson et al, 2008). These and other processes were hypothesized to have driven A T changes in the Baltic Sea (Müller et al, 2016). There, an increase in A T of 3.4 µmol kg −1 yr −1 was observed from 1995 to 2014 (mean salinity = 7).…”

Section: Discussionmentioning

confidence: 99%

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Coastal ocean acidification and increasing total alkalinity in the northwestern Mediterranean Sea

et al. 2017

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Abstract. Coastal time series of ocean carbonate chemistry are critical for understanding how global anthropogenic change manifests in near-shore ecosystems. Yet, they are few and have low temporal resolution. At the time series station Point B in the northwestern Mediterranean Sea, seawater was sampled weekly from 2007 through 2015, at 1 and 50 m, and analyzed for total dissolved inorganic carbon (C T ) and total alkalinity (A T ). Parameters of the carbonate system such as pH (pH T , total hydrogen ion scale) were calculated and a deconvolution analysis was performed to identify drivers of change. The rate of surface ocean acidification was −0.0028 ± 0.0003 units pH T yr −1 . This rate is larger than previously identified open-ocean trends due to rapid warming that occurred over the study period (0.072 ± 0.022 • C yr −1 ). The total pH T change over the study period was of similar magnitude as the diel pH T variability at this site. The acidification trend can be attributed to atmospheric carbon dioxide (CO 2 ) forcing (59 %, 2.08 ± 0.01 ppm CO 2 yr −1 ) and warming (41 %). Similar trends were observed at 50 m but rates were generally slower. At 1 m depth, the increase in atmospheric CO 2 accounted for approximately 40 % of the observed increase in C T (2.97 ± 0.20 µmol kg −1 yr −1 ). The remaining increase in C T may have been driven by the same unidentified process that caused an increase in A T (2.08 ± 0.19 µmol kg −1 yr −1 ). Based on the analysis of monthly trends, synchronous increases in C T and A T were fastest in the spring-summer transition. The driving process of the interannual increase in A T has a seasonal and shallow component, which may indicate riverine or groundwater influence. This study exemplifies the importance of understanding changes in coastal carbonate chemistry through the lens of biogeochemical cycling at the land-sea interface. This is the first coastal acidification time series providing multiyear data at high temporal resolution. The data confirm rapid warming in the Mediterranean Sea and demonstrate coastal acidification with a synchronous increase in total alkalinity.

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Section: Discussioncontrasting

confidence: 56%

Section: Discussionmentioning

confidence: 99%

Coastal ocean acidification and increasing total alkalinity in the northwestern Mediterranean Sea

et al. 2017

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“…The control scenario is by no means constant, but reflects the climate-driven changes expected according to the A1B storyline and changes in deposition of emissions from other sources following RCP4.5. Müller et al (2016) have recently reviewed the temporal development of alkalinity in the Baltic Sea, and have shown that the alkalinity is currently increasing. This may be connected to the observed increase in organic carbon concentrations (Fleming-Lehtinen et al 2015), since it has been shown that organic matter contributes to the total alkalinity in the Baltic Sea (Kulinski et al 2014).…”

Section: Discussionmentioning

confidence: 99%

The potential future contribution of shipping to acidification of the Baltic Sea

Turner

Edman²,

Gallego-Urrea

et al. 2017

Ambio

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International regulation of the emission of acidic sulphur and nitrogen oxides from commercial shipping has focused on the risks to human health, with little attention paid to the consequences for the marine environment. The introduction of stricter regulations in northern Europe has led to substantial investment in scrubbers that absorb the sulphur oxides in a counterflow of seawater. This paper examines the consequences of smokestack and scrubber release of acidic oxides in the Baltic Sea according to a range of scenarios for the coming decades. While shipping is projected to become a major source of strong acid deposition to the Baltic Sea by 2050, the long-term effect on the pH and alkalinity is projected to be significantly smaller than estimated from previous scoping studies. A significant contribution to this difference is the efficient export of surface water acidification to the North Sea on a timescale of 15–20 years.

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“…The reduction of alkalinity through the deposition of strong acids is also a potential monitoring option, but would need to assume an otherwise constant alkalinity. This assumption may not always be true: for example, a recent study has shown that the alkalinity of the Baltic Sea is increasing, presumed due to changes in runoff (Müller et al, 2016). A more promising option for monitoring the releases due to combustion of heavy fuel oil may be the metal vanadium.…”

Section: Monitoring Of Ship Plumes and Scrubbersmentioning

confidence: 99%

Shipping and the environment: Smokestack emissions, scrubbers and unregulated oceanic consequences

Turner

Hassellöv

Ytreberg

et al. 2017

Elementa: Science of the Anthropocene

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While shipping has long been recognised as a very carbon-efficient transport medium, there is an increasing focus on its broader environmental consequences. The International Maritime Organisation is responsible for the regulation of ship emissions arising from fuel combustion. Their current regulations are, however, much less strict than those applying to land-based transport within the European Union. Five different groups of pollutant emission from ship smokestacks are addressed in this paper: sulphur oxides, nitrogen oxides, particulate matter, organic matter and metals. The reduction of sulphur oxide emissions into the atmosphere using scrubber technology adds another dimension to the discussion, as this approach results in focused discharge of some pollutants to the surface water. A scoping calculation shows that an open-loop scrubber on a medium-sized ship could discharge more copper and zinc daily to the surface water than the ship’s antifouling paint. The use of antifouling paint in the European Union is subject to a prior risk assessment, but scrubber discharges are not subject to any such risk assessment. This situation presents a problem from the perspective of the Marine Strategy Framework Directive, as environmental monitoring programmes in some coastal areas of the Baltic Sea have shown that levels of both copper and zinc exceed environmental quality standards. To fulfil the Marine Strategy Framework Directive requirements and achieve Good Environmental Status, having knowledge of the magnitude of different anthropogenic pressures is important. Metal inputs from open-loop scrubbers have been largely neglected until now: some metals have the potential to serve as tracers for monitoring scrubber discharges.

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

Cited by 96 publications

References 62 publications

Coastal ocean acidification and increasing total alkalinity in the northwestern Mediterranean Sea

Coastal ocean acidification and increasing total alkalinity in the northwestern Mediterranean Sea

The potential future contribution of shipping to acidification of the Baltic Sea

Shipping and the environment: Smokestack emissions, scrubbers and unregulated oceanic consequences

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

Cited by 96 publications

References 62 publications

Coastal ocean acidification and increasing total alkalinity in the northwestern Mediterranean Sea

Coastal ocean acidification and increasing total alkalinity in the northwestern Mediterranean Sea

The potential future contribution of shipping to acidification of the Baltic Sea

Shipping and the environment: Smokestack emissions, scrubbers and unregulated oceanic consequences

Contact Info

Product

Resources

About

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