Abstract
“They call it life, we call it pollution” is an infamous quote which ignores many facts about why carbon dioxide (CO2) poses a significant problem for the ocean. But before we get to this, let’s start at the beginning. All organisms on Earth require a particular set of elements for growth. In the case of plants, these elements are needed to synthesise organic matter in a process called primary production via photosynthesis, and in the case of animals, these elements are directly assimilated by either consuming plant material or by preying on other animals. In this respect, one of the key elements is carbon. Being the molecular backbone for a number of vital organic compounds such as sugars, proteins and nucleic acids (containing genetic information), carbon can be considered as the building block of life.
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11.1 Introduction
“They call it pollution, we call it life” is an infamous quote which ignores many facts about why carbon dioxide (CO2) poses a significant problem for the ocean. But before we get to this, let’s start at the beginning.
All organisms on Earth require a particular set of elements for growth. In the case of plants, these elements are needed to synthesise organic matter in a process called primary production via photosynthesis, and in the case of animals, these elements are directly assimilated by either consuming plant material or by preying on other animals. In this respect, one of the key elements is carbon. Being the molecular backbone for a number of vital organic compounds such as sugars, proteins and nucleic acids (containing genetic information), carbon can be considered as the building block of life. Similar requirements also apply to bacteria, fungi and viruses, which stand outside the plant and animal kingdoms. However, carbon is not only exchanged between organisms. There are in fact much larger reservoirs on Earth and fluxes in between, especially in the marine environment (Figure 11.1). In their entirety, they are referred to as the global carbon cycle.
11.2 The Global Carbon Cycle
The largest carbon reservoir on Earth are sedimentary rocks in its crust and upper mantle (i.e. the lithosphere). It is approximately three orders of magnitude (×1000) larger than all other reservoirs combined (Falkowski et al. 2000), however, it has the slowest exchange rates (Figure 11.1). As a consequence, it requires relatively large changes to these fluxes and typically long geologic time scales (on the order of thousands to millions of years) to significantly affect the other reservoir sizes.
The second-largest carbon reservoir are the oceans, where about 900 Pg are found in the surface ocean (1 Pg equals 1015 g or 109, or 1 billion tonnes) and approximately 37,100 Pg in the intermediate and deep ocean, mostly in the form of dissolved inorganic carbon (DIC) (Box 11.1). Given the relatively large exchange rates between the surface and the deep ocean and also with the atmosphere, small changes can lead to a significant redistribution, for instance in the atmosphere, which is one of the smaller reservoirs. As an example, shutting down the organic carbon pump (see below) could easily double atmospheric CO2 levels, based on a back-on-the-envelope calculation, assuming a mean deep ocean DIC enrichment of 50 μmol kg−1 (compare Figure 11.2a) at an overall volume of ~1.3 × 1018 m3 of seawater and an average depth of 3.7 km (Eakins and Sharman 2010).
11.3 The Physical and Biological Carbon Pumps
The so-called carbon pumps describe the flux of dissolved inorganic carbon and total alkalinity from the ocean surface to depth. They are operating against a concentration gradient, and their relative strengths drive the direction of CO2 air-sea gas exchange (Figure 11.3b).
The physical carbon pump is based on increasing CO2 solubility when warmer waters cool. Subsequently when sea ice forms at cold high latitudes in the North Atlantic and around Antarctica, the DIC-rich surface waters become particularly dense (due to high salinity) and sink (Figure 11.3b). Such deep-water formation at high latitudes is responsible for large-scale ocean circulation with water masses flowing at depth from the North to the South Atlantic, and into the Indian and Pacific Oceans where they are eventually subject to upwelling and return as surface currents back to the North Atlantic. The biological carbon pump can be split into two; the organic carbon (or soft tissue) pump, and the carbonate counter pump. As the name suggests the latter operates in the opposite way to the former in terms of atmospheric CO2 uptake of the surface ocean (Figure 11.3b).
The organic carbon pump is driven by marine phytoplankton (microscopic unicellular plants) which, as mentioned above, fix CO2 into organic matter in the sun-lit surface ocean via photosynthesis. Most of the carbon will end up in the particulate rather than the dissolved organic fraction and rain down to the ocean floor when particles have a higher density than the surrounding seawater. During downward transport most of the particulate organic carbon (POC) will be converted back to CO2 by bacterial respiration and only a fraction of the ~11 Pg exported each year will be buried in sediments (compare Figures 11.1 and 11.3b).
The carbonate counter pump is driven by calcium carbonate (CaCO3) formation of open ocean organisms, mainly calcifying phytoplankton (coccolithophores), and zooplankton (foraminifera and pteropods). As the precipitation of CaCO3 shifts the carbonate chemistry equilibrium towards lower pH and hence higher CO2 (Box 11.2), the ocean’s storage capacity for the latter is reduced. At present, CaCO3 is a stable mineral in most of the surface ocean, an important fact as some organisms critically rely on these minerals (see Section 11.4.2 for details). Being denser than seawater, however, there is a steady rain of CaCO3 to the sea floor, estimated at approximately 1 Pg C per year. About 90% of this will dissolve as the saturation state decreases with pressure at depth and waters eventually become undersaturated. Although CaCO3 formation in the surface ocean has an immediate opposite effect on CO2 air-sea gas exchange in comparison to photosynthesis, CaCO3 is thought to strengthen the efficiency of the organic carbon pump as aggregates of POC and the much denser CaCO3 will sink more rapidly (Klaas and Archer 2002; De La Rocha and Passow 2014). This would move respiration to deeper layers and keep the CO2 produced away from atmospheric contact for longer time. As a consequence, this would increase the surface to depth DIC gradient and allow for more atmospheric CO2 to be stored at depth.
Whether the positive effects of ballasting on oceanic CO2 uptake outweigh the negative effects of CaCO3 production is difficult to reconcile, however, models suggest that they may cancel each other out (e.g. Barker et al. 2003; Kvale et al. 2021). While the two carbon pumps govern biogeochemical element cycling in the ocean, they are part of a bigger picture, the global carbon cycle, which is currently perturbed by human activities.
11.4 Human-Induced Changes to the Global Carbon Cycle
Since the beginning of the Industrial Revolution in the late eighteenth century, the burning of fossil fuels such as oil, gas and coal, as well as cement production, has come with emissions of the greenhouse gas carbon dioxide (CO2). Together with changes in land-use and deforestation, these anthropogenic emissions have significantly changed the flow of carbon between land, ocean and atmosphere, impacting respective reservoir sizes (Figure 11.1). From the ~430 Pg of carbon stemming from fossil fuels and cement production, ~275 Pg have been accumulating in the atmosphere. With ~235 Pg estimated to originate from land-use changes and ~ 165 Pg having entered the oceans, the terrestrial carbon sink is estimated to be ~225 Pg. For a long time, this has been considered the result of CO2 _ enhanced photosynthesis coupled with vast amounts of nitrogen and phosphorus being released into the environment as fertiliser, enhancing growth in the last 100 years. Although this simple mass balance is similar to estimates from various dynamic vegetation models (Le Quéré et al. 2018), it has been proposed recently that almost half of the current annual land sink for anthropogenic carbon is not linked to an increase in terrestrial biomass storage. Rather, it comprises fossil fuels which are not turned into CO2 (i.e. plastics and bitumen), harvested wood products and CO2 being absorbed by cement carbonation in concrete structures. Hence, at the moment, it is difficult to put a number on the biological component of the terrestrial carbon sink.
Nevertheless, the human-induced changes to the global carbon cycle in general, and the atmosphere in particular are driving climate change by affecting Earth’s radiative balance, causing mean surface temperatures to increase. While this is an accepted fact within the scientific community after decades of research–the first assessment report on climate change by the Intergovernmental Panel on Climate Change (IPCC) dates back to the 1990s and the most recent report was released in 2021 (IPCC 1990, 2021)–there are groups of activists campaigning against this scientific consensus. A memorable anecdote is the release of a television advertisement by the Competitive Enterprise Institute, a neoconservative think tank in May 2006. This video appeared to be targeting Al Gore’s film An Inconvenient Truth, which was about to be released in cinemas worldwide at the time and highlighted the connections between a fossil fuel-based economy and climate change. In an attempt to dismiss the negative effects of increasing atmospheric CO2 levels on Earth’s climate system and referring to the fact that plants utilise CO2 in photosynthesis for growth, the advertisement culminated in the claim “CO2: They call it pollution, we call it life!”.
Today we are in a situation where it appears highly unlikely to be able to stabilise global temperatures at 1.5 ºC above pre-industrial levels until the end of this century (IPCC 2018). This was a goal adopted by 179 states that ratified the United Nations Paris Agreement in 2015, in order to keep the threats of temperature-driven global climate change (e.g. ice melt, sea level rise, and intensification of extreme weather events) within manageable boundaries. However, these are not the only issues with increasing levels of atmospheric CO2, as it also has a direct impact on the world’s oceans.
11.4.1 Ocean Acidification
In the last 250 years, atmospheric CO2 levels have steadily increased from 280 ppm (parts per million) to 417 ppm in 2022 (Friedlingstein et al. 2022). As a result of equilibration at the air-sea interface, substantial amounts of this anthropogenic CO2 have also made its way into the ocean (Figure 11.4). When CO2 dissolves in seawater it forms carbonic acid, which reduces its pH (Equation 11.2). This is known as ocean acidification and has been coined the evil twin of climate change (Pelejero et al. 2010). The pH of the ocean has already dropped by ~0.1 units since the Industrial Revolution, which is equivalent to a ~30% increase in acidity (note that the pH scale is logarithmic). This drop in pH has changed carbonate chemistry speciation (Box 11.1), with potentially significant implications for a number of key species in the ocean.
11.4.2 Potential Effects of Ocean Acidification on Key Organisms and Processes of the Marine Carbon Cycle
With the realisation that ongoing ocean acidification might pose a threat to marine organisms and ecosystems, research into the potential biological responses has grown exponentially during the last two decades. Today the number of studies is probably in the thousands (compare Gattuso and Hansson 2011). Since it is beyond the scope of this Chapter to cover all of them, we will focus on key groups and processes in terms of impact on global carbon cycling.
One of the first groups suspected to be affected by ocean acidification was calcium carbonate (CaCO3) producing (or calcifying) organisms. The reasoning was that the CO2 _ induced reduction in pH would reduce carbonate ion concentrations (Box 11.2) and hence substrate availability for calcification, in turn negatively affecting CaCO3 precipitation rates (Broecker and Takahashi 1966). Today, a majority of studies (including meta-analyses) have indeed found that calcification rates in most marine taxa are negatively impacted by ocean acidification. This includes hard corals, calcifying phytoplankton (a very important taxon for marine carbon cycling at the base of marine food webs and for marine carbon cycling Figure 11.5), algae, foraminifera, pteropods and molluscs (Gattuso and Hansson 2011; Kroeker et al. 2010, 2013; Schulz et al. 2017), although it has to be acknowledged that there are species-specific differences and sensitivities.
In this respect, it is interesting to note that there is still an ongoing debate on the physiological mechanisms underlying the susceptibility of calcification to ocean acidification. Calcification is a process under tight cellular control and involves diffusion and transport of ions across membranes. While there is a consensus that calcification rates are a function of the internal saturation state at the site of CaCO3 precipitation, the key question is by which external bulk seawater carbonate chemistry parameter(s) it is governed. For coccolithophores, there is experimental evidence that it is decreasing seawater pH levels which are unfavourable for calcification (e.g. Bach et al. 2015). The underlying principle is a reduction in the internal to external electrochemical proton gradient, which is thought to increase the costs of removing the protons (e.g. Gafar et al. 2019 and references therein) that are generated by CaCO3 precipitation (Box 11.2). These basic principles could also be the mechanisms underlying the sensitivity of calcification in other marine organisms. While this idea has recently been advocated (Cyronak et al. 2016a, b), it has also been contested (Waldbusser et al. 2016).
The other key group of marine organisms (when it comes to global carbon cycling) are photoautotrophs. Since they harness the energy of light to fix CO2 in photosynthesis, it might be expected that this process could profit from ocean acidification. Indeed, there is (with the exception of calcifying algae) a trend towards increased photosynthesis in response to ocean acidification. However, it appears that photosynthesising calcifiers (such as corals and coccolithophores) might benefit less than non-calcifying groups such as the main contributor to ocean primary productivity [i.e. diatoms, fleshy algae and seagrasses (Kroeker et al. 2010, 2013)]. Again, it is important to stress that sensitivities are species-specific.
While most of the experiments on the effects of ocean acidification on marine calcification and primary production have been conducted on single species, to predict future changes it is necessary to include important factors on the ecosystem level such as species interaction (e.g. predation, and competition for resources). This requires either larger-scale manipulative in-situ studies or manipulative incubations with entire communities. A good example of the former are experiments which showed that net calcification rates of an entire reef–including a variety of calcifiers ranging from corals to coralline algae and foraminifera in sediments–were decreasing with decreasing pH and vice versa (Albright et al. 2016, 2018). The future survival of coral reef ecosystems depends on this intricate budget, taking into account all CaCO3 precipitation and dissolution processes. In addition, mass balance calculations including corals and sediments suggest that below a seawater aragonite saturation state of 2.55, reefs with 5% coral cover might become net dissolving (Eyre et al. 2018). Depending on the future CO2 emission scenario, this threshold could be reached well before the turn of this century (IPCC 2013), in particular for reefs that experience upwelling of naturally CO2-rich deep waters, such as documented along the East Australian coast, amplifying ocean acidification (Schulz et al. 2019).
11.4.3 Potential Effects of Ocean Acidification on Biogeochemical Element Cycling
Changes to the efficiency and/or strength of the biological carbon pumps are bound to affect air-sea CO2 gas exchange (compare Figure 11.3). Hence, ongoing ocean acidification-driven changes would constitute a feedback loop, either amplifying or dampening increasing atmospheric CO2 levels (Riebesell et al. 2009). As described above, the mineral ballasting (CaCO3 or biogenic silica) of particulate organic matter produced in the sun-lit surface ocean, which is otherwise nearly neutrally buoyant, enhances the transport of organically bound CO2 into the deep ocean. Hence, reductions in CaCO3 production there are thought to negatively impact this export flux (e.g. Armstrong et al. 2002; Boyd and Doney 2002). Experimental assessment, however, has proven difficult, in part due to the large distances involved (1000s of metres). However, on smaller scales (10s of metres) in mesocosm experiments, ocean acidification has been found to significantly reduce the bloom-forming potential of the cosmopolitan coccolithophore Emiliania huxleyi (Figure 11.5) which in turn reduced the amount of sedimenting organic carbon by approximately a quarter (Riebesell et al. 2018). As this was directly related to reductions in sinking speed velocities with reduced CaCO3 production (Bach et al. 2016), it might be reasonable to assume this mechanism is also operating in the real ocean. When it comes to biogenic silica production by diatoms, the other important ballast mineral, it is more complicated as of a more variable response to ocean acidification (Bach and Taucher 2019). Although, overall contributions of diatoms to primary production have recently been projected to decrease in the future ocean (Trèguer et al. 2018), with the exception of the Southern Ocean, in which however, the amount of cellular silica ballast produced by diatoms have been found to decrease with ocean acidification (Petrou et al. 2019).
The shift from larger to smaller sized picophytoplankton as a result of ocean acidification found in a number of experiments (see Schulz et al. 2017 and references therein), could have a similar effect on the flux of organic carbon to depth and hence atmospheric CO2 levels. This is based on observations of lower export efficiencies at a number of open ocean sites with significant picophytoplankton community contributions, although considerable variability exists locally and seasonally (see De La Rocha and Passow 2014 for a review).
In summary, experiments on the effects of ocean acidification on surface ocean carbon cycling imply that positive could outweigh negative feedbacks, amplifying increasing levels of atmospheric carbon dioxide.
11.5 Outlook
Without a reduction in anthropogenic CO2 emissions, the future ocean will continue to become more acidic. Depending on CO2 emission scenario extrapolations to the year 2100 suggest a further decrease in pH of ~0.2‒0.3 units (IPCC 2013). The direction and magnitude of all the feedback mechanisms associated with ocean acidification are currently difficult to project, but clearly there will be significant effects on certain organisms and ecosystems.
To successfully reduce anthropogenic CO2 emissions will require a combination of legislative and technological advances. Several significant steps have been made in trying to curb the emissions of CO2, such as the UN Paris Agreement and national arrangements such as Canada’s Greenhouse Gas Pollution Price Act. However, despite these important steps, CO2 emissions as of today are still increasing (Le Quéré et al. 2018), highlighting the need to further strengthen our efforts. In terms of technological advances, the efficiency of the leading multi-junction cell solar panels has reached ~46% (Green et al. 2018), and renewable energy output is increasing globally (as demand has unfortunately too), supplying almost 30% of global electricity demand in 2020 (IEA 2020). With continued advancement in technology, along with the implementation of legislative tools, a zero-emission future is achievable, but if it will be quick enough remains to be seen.
11.6 Summary
Carbon is considered the building block of life. It is exchanged between organisms, but there are much larger reservoirs and fluxes on Earth, especially in the marine environment. Carbon reservoirs include sedimentary rocks in the Earth’s crust and upper mantle (primarily), the oceans, the soils on land, and to a lesser extent the atmosphere. Significant changes have occurred since the Industrial Revolution, when global cycling of carbon (the flow of carbon in and out of a reservoir) was near balanced in a quasi-steady state (Pongratz et al. 2009).
Carbon pumps are either biological or physical and operate against a concentration gradient. Their relative strengths drive the direction of CO2 air-sea gas exchange, and govern biogeochemical element cycling in the ocean. The physical carbon pump is driven by increasing CO2 solubility when warmer waters cool. When sea ice forms in the North Atlantic and around Antarctica, the DIC-rich surface waters increase in density and sink. This is driving large-scale ocean circulation.
The biological carbon pump includes the organic carbon pump and the carbonate counter pump, and these operate in an opposite direction in terms of atmospheric CO2 uptake. The organic carbon pump is driven by the constant rain of particulate organic matter from the surface ocean, where it had been produced by photosynthesis. During sinking, most particulate organic carbon will be converted back to CO2 by bacterial respiration. The carbonate counter pump is driven by CaCO3 formation by marine organisms, whereby precipitation of CaCO3 shifts the carbonate chemistry equilibrium towards lower pH and hence a higher CO2 concentration.
Anthropogenic CO2 emissions since the Industrial Revolution, along with changes in land-use and deforestation, have significantly altered the flow of carbon between land, oceans, and the atmosphere. These human-induced changes to the global carbon cycle in general, and the atmosphere in particular, are driving current climate and ocean change. In the last 250 years, atmospheric CO2 levels have increased from 280 to 417 ppm (in 2022). Substantial amounts of CO2 have made their way into the ocean causing ocean acidification, with a reduction in the pH of surface waters by ~0.1 units (equivalent to a 30% increase in acidity) as of today. This will most likely have increasing implications for numerous marine keystone species. Furthermore, experiments on the effects of ocean acidification on surface ocean carbon cycling suggest that positive feedback effects are likely to amplify increasing levels of atmospheric CO2. A combination of legislative and technological advances is needed to reduce anthropogenic CO2 emissions and mitigate global climate/ocean change.
11.7 Study Questions and Activities
-
1.
Describe how pH influences the proportions of CO2, \({{\text{CO}_{3}}^{2-} }\) and \({{\text{HCO}_{3}}^{-} }\) in water and vice versa.
-
2.
Discuss the various carbon pumps and how they influence marine carbon cycling.
-
3.
Describe how CaCO3 formation in the surface ocean has the opposite effect to photosynthesis on CO2 air-sea gas exchange.
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4.
Explain the meaning of “saturation state”, and how this is relevant to calcifying marine organisms.
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5.
Summarise The United Nations Paris Agreement, and report up-to-date information regarding its implementation.
Abbreviations
- CA:
-
Carbonate alkalinity
- DIC:
-
Dissolved inorganic carbon
- IPCC:
-
Intergovernmental Panel on Climate Change
- Ωarag:
-
Saturation state for aragonite
- Ωcalc:
-
Saturation state for calcite
- POC:
-
Particulate organic carbon
- ppm:
-
Parts per million
- Pg:
-
Peta gram
- TA:
-
Total alkalinity
- TOC:
-
Total organic carbon
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Schulz, K.G., Maher, D.T. (2023). Atmospheric Carbon Dioxide and Changing Ocean Chemistry. In: Reichelt-Brushett, A. (eds) Marine Pollution – Monitoring, Management and Mitigation . Springer Textbooks in Earth Sciences, Geography and Environment. Springer, Cham. https://doi.org/10.1007/978-3-031-10127-4_11
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