Abstract
Abstract. The ocean has become more acidic over the last 200 years in response increasing atmospheric carbon dioxide (CO2) levels. Documenting how the ocean has changed is critical for assessing how these changes impact marine ecosystems and for the management of marine resources. Here we use present-day ocean carbon observations, from shelf and offshore waters around Australia, combined with neural network mapping of CO2, sea surface temperature, and salinity to estimate the current seasonal and regional distributions of carbonate chemistry (pH and aragonite saturation state). The observed changes in atmospheric CO2 and sea surface temperature (SST) and climatological salinity are then used to reconstruct pH and aragonite saturation state changes over the last 140 years (1870–2013). The comparison with data collected at Integrated Marine Observing System National Reference Station sites located on the shelf around Australia shows that both the mean state and seasonality in the present day are well represented, with the exception of sites such as the Great Barrier Reef. Our reconstruction predicts that since 1870 decrease in aragonite saturation state of 0.48 and of 0.09 in pH has occurred in response to increasing oceanic uptake of atmospheric CO2. Large seasonal variability in pH and aragonite saturation state occur in southwestern Australia driven by ocean dynamics (mixing) and in the Tasman Sea by seasonal warming (in the case of the aragonite saturation state). The seasonal and historical changes in aragonite saturation state and pH have different spatial patterns and suggest that the biological responses to ocean acidification are likely to be non-uniform depending on the relative sensitivity of organisms to shifts in pH and saturation state. This new historical reconstruction provides an important link to biological observations that will help to elucidate the consequences of ocean acidification.
Highlights
The ocean plays a key role in reducing the rate of global climate change, absorbing approximately 30 % of the anthropogenic CO2 emitted over the last 200 years (Ciais et al, 2013) and more than 25 % of current CO2 emissions (Le Quéré, 2015)
To explore how Australia’s marine environment has changed, we have synthesized newly acquired in situ observations of carbon chemistry around Australia to (i) provide a new estimate of the mean state and seasonality of pH and the aragonite saturation state and (ii) reconstruct the changes in ocean acidification around Australia since 1870
In this work we developed a new total alkalinity–salinity relationship for the Australian region
Summary
The ocean plays a key role in reducing the rate of global climate change, absorbing approximately 30 % of the anthropogenic CO2 emitted over the last 200 years (Ciais et al, 2013) and more than 25 % of current CO2 emissions (Le Quéré, 2015). Over the past 200 years, it is estimated that there has been a 0.1 unit reduction in the ocean’s surface pH or a 26 % increase in the concentration of hydrogen ion concentrations in seawater (Doney et al, 2009). Current projections suggest that the increase in hydrogen ion concentration is likely to be greater than 100 % (than the preindustrial period) by the end of the century under highemissions trajectories (see, e.g., Matear and Lenton, 2014). These changes will persist for many millennia (see, e.g., Frolicher and Joos, 2010). Factors that can be impacted include reproductive health, organism growth and physiology, species composition and distributions, food web structure, and nutrient availability
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