Indicator Assessment

Ocean acidification

Indicator Assessment

Prod-ID: IND-349-en

Also known as: CLIM 043

Published 20 Nov 2012 Last modified 11 May 2021

9 min read

This is an old version, kept for reference only.

Go to latest version

Topics: Climate change adaptation Water and marine environment

This page was archived on 24 Aug 2017 with reason: A new version has been published

Surface-ocean pH has declined from 8.2 to 8.1 over the industrial era due to the growth of atmospheric CO₂ concentrations. This decline corresponds to a 30 % change in oceanic acidity.
Observed reductions in surface-water pH are nearly identical across the global ocean and throughout Europe’s seas.
Ocean acidification in recent decades is occurring a hundred times faster than during past natural events over the last 55 million years.
Ocean acidification already reaches into the deep ocean, particularly in the high latitudes.
Average surface-water pH is projected to decline further to 7.7 or 7.8 by the year 2100, depending on future CO₂ emissions. This decline represents a 100 to 150 % increase in acidity.

Ocean acidification may affect many marine organisms within the next 20 years and could alter marine ecosystems and fisheries.

Decline in pH measured at the Aloha station as part of the Hawaii Ocean time-series

Note: Aloha station pH time series. Changes here are similar to those that are observed at a much shorter time scale in Europe.

Data source:

Data provenance info is missing.

Downloads and more info

Past trends

In December 2011, the atmospheric CO₂ level reached 392 ppm, which is 40 % more than the pre-industrial concentration (280 ppm); half of that increase has occurred in the last 30 years. Ocean pH has been reduced from 8.2 to 8.1 over the industrial era, which corresponds to a 30 % increase in ocean acidity (defined here as the hydrogen ion concentration). This change has occurred at a rate that is about a hundred times faster than any change in acidity experienced during the last 55 million years. The current decline in pH is already measurable at the three ocean time series stations that are suitable to evaluate long-term trends, located offshore of Hawaii, Bermuda and the Canary Islands. Figure 1 shows the time series from Hawaii, which is the longest and best known one, and the changes here are similar to those that are observed at a much shorter time scale in Europe. The measured reductions in surface pH at those stations match exactly the values calculated on the basis of increasing atmospheric CO₂ concentrations, assuming thermodynamic equilibrium between the surface ocean and the atmosphere [i].

Projections

Average surface-water pH is projected to decline further to 7.7 or 7.8 by the year 2100, depending on future CO₂ emissions. This decline represents a 100 to 150 % increase in acidity. When atmospheric CO₂ reaches 450 ppm, parts of the Southern Ocean will start becoming corrosive to calcium carbonate during winter [ii]. Ten per cent of the Arctic Ocean may become corrosive to calcium carbonate already by 2020 [iii], and surface waters of the Baltic Sea will still become corrosive well before the end of the century. In the Black Sea and Mediterranean Sea there is no danger of surface waters becoming corrosive to calcium carbonate before 2100, but they will suffer sharp reductions in carbonate ion concentrations (Med Sea - 37 %; Black Sea - 45 %). These rapid chemical changes are an added pressure on marine calcifiers and ecosystems of the European seas that are already heavily suffering from other anthropogenic influences.

Without dramatic actions to curb CO₂ emissions, recovery from human-induced acidification will require thousands of years for the Earth system to re-establish roughly similar ocean chemical conditions [iv] and millions of years for coral reefs to return, based on palaeo-records of natural coral reef extinction events [v].

[i] N.R. Bates, „Ocean Carbon Time Series“ (IOCCP, 2005), http://www.ioccp.org/Docs/TimeSeriesCompileNRB.pdf; J. Magdalena Santana-Casiano et al., „The interannual variability of oceanic CO₂ parameters in the northeast Atlantic subtropical gyre at the ESTOC site“, Global Biogeochemical Cycles 21, Nr. 1 (März 8, 2007), doi:10.1029/2006GB002788; J.E. Dore et al., „Physical and biogeochemical modulation of ocean acidification in the central North Pacific“, Proceedings of the National Academy of Sciences 106 (2009): 12235–12240., doi:10.1073/pnas.0906044106.

[ii] B. I. McNeil and R. J. Matear, „Southern Ocean acidification: A tipping point at 450-ppm atmospheric CO₂“, Proceedings of the National Academy of Sciences 105, Nr. 48 (November 20, 2008): 18860–18864, doi:10.1073/pnas.0806318105.

[iii] M. Steinacher et al., „Imminent ocean acidification in the Arctic projected with the NCAR global coupled carbon cycle-climate model“, Biogeosciences 6, Nr. 4 (April 6, 2009): 515–533, doi:10.5194/bg-6-515-2009.

[iv] David Archer, „Fate of fossil fuel CO₂ in geologic time“, Journal of Geophysical Research 110, Nr. C9 (2005), doi:10.1029/2004JC002625; David Archer and Victor Brovkin, „The millennial atmospheric lifetime of anthropogenic CO₂“, Climatic Change 90, Nr. 3 (Juni 4, 2008): 283–297, doi:10.1007/s10584-008-9413-1; Toby Tyrrell, John G. Shepherd, and Stephanie Castle, „The long-term legacy of fossil fuels“, Tellus B 59, Nr. 4 (September 2007): 664–672, doi:10.1111/j.1600-0889.2007.00290.x.

[v] J. E. N Veron, A reef in time : the Great Barrier Reef from beginning to end (Cambridge, Mass.: Belknap Press of Harvard University Press, 2008).

Supporting information

Indicator definition

Decline in ocean acidity

Units

acidity (pH)

Rationale

Justification for indicator selection

Across the ocean, the pH of surface waters has been relatively stable for millions of years. Over the last million years, average surface-water pH oscillated between 8.3 during cold periods (e.g. during the last glacial maximum, 20 000 years ago) and 8.2 during warm periods (e.g. just prior to the industrial revolution). Human activities are threatening this stability by adding large quantities of CO₂ to the atmosphere, which is subsequently partially absorbed in the ocean. This process is referred to as ocean acidification because sea water pH is declining, even though ocean surface waters will remain alkaline.

When CO₂ is absorbed by the ocean, it reacts with water, producing carbonic acid. The role of the carbonate ion is special because it acts as a buffer, helping to limit the decline in ocean pH; however, it is being used up as we add more and more anthropogenic CO₂ to the ocean. As carbonate ion concentrations decline, so does the ocean’s capacity to take up anthropogenic CO₂. Currently, the ocean takes up about one fourth of the global CO₂ emissions from combustion of fossil fuels, cement production and deforestation. Hence, the ocean serves mankind by moderating atmospheric CO₂ and thus climate change, but at a cost, namely changes in its fundamental chemistry.

It has been shown that corals, mussels, oysters and other marine calcifiers have a more difficult time constructing their calcareous shell or skeletal material as the concentration of carbonate ions decreases. Most, but not all, marine calcifying organisms exhibit the same difficulty. Furthermore, pH is a measure which affects not only inorganic chemistry but also many biological molecules and processes, including enzyme activities, calcification and photosynthesis. Thus, anthropogenic reductions in sea water pH could affect entire marine ecosystems. A comprehensive recent study suggests that all coral reefs will cease to grow and start to dissolve at an atmospheric CO₂ level of 560 ppm due to the combined effects of acidification and warming. This CO₂ concentration would be attained by 2050 under high business-as-usual emissions scenarios. Other organisms and ecosystems are likely to have different thresholds.

Scientific references

IPCC, 2013: Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1535 pp.

Policy context and targets

Context description

In April 2013 the European Commission presented the EU Adaptation Strategy Package (http://ec.europa.eu/clima/policies/adaptation/what/documentation_en.htm). This package consists of the EU Strategy on adaptation to climate change /* COM/2013/0216 final */ and a number of supporting documents. One of the objectives of the EU Adaptation Strategy is Better informed decision-making, which should occur through Bridging the knowledge gap and Further developing Climate-ADAPT as the ‘one-stop shop’ for adaptation information in Europe. Further objectives include Promoting action by Member States and Climate-proofing EU action: promoting adaptation in key vulnerable sectors. Many EU Member States have already taken action, such as by adopting national adaptation strategies, and several have also prepared action plans on climate change adaptation.

The European Commission and the European Environment Agency have developed the European Climate Adaptation Platform (Climate-ADAPT, http://climate-adapt.eea.europa.eu/) to share knowledge on observed and projected climate change and its impacts on environmental and social systems and on human health; on relevant research; on EU, national and subnational adaptation strategies and plans; and on adaptation case studies.

Targets

No targets have been specified.

Methodology

Methodology for indicator calculation

The time series shows both direct measurement data from the Aloha station pH as well as calculations for gap filling (see methodology reference below).

A trend line has been added.

Methodology for gap filling

The methodology for gap filling is described in the reference below.

Methodology references

Dore et al. 2009: Physical and biogeochemical modulation of ocean acidification in the central North Pacific. Dore, J. E., Lukas, R., Sadler, D. W., Church, M. J. and Karl, D. M. (2009) Proceedings of the National Academy of Sciences 106, 12235–12240. doi:10.1073/pnas.0906044106

Uncertainties

Methodology uncertainty

Not applicable

Data sets uncertainty

In general, changes related to the physical and chemical marine environment are better documented than biological changes because links between cause and effect are better understood and often time series of observations are longer. Ocean acidification occurs as a consequence of well-defined chemical reactions, but its rate and biological consequences on a global scale is subject to research.

Further information on uncertainties is provided in Section 1.7 of the EEA report on Climate change, impacts, and vulnerability in Europe 2012 (http://www.eea.europa.eu/publications/climate-impacts-and-vulnerability-2012/)

Rationale uncertainty

No uncertainty has been specified

Data sources

Hawaii Ocean Time-series (HOT)
provided by University of Hawaii
Coupled Model Intercomparison Project Phase 5 - CMIP5
provided by Lawrence Livermore National Laboratory (LLNL)

Other info

DPSIR: State
Typology: Descriptive indicator (Type A - What is happening to the environment and to humans?)

Indicator codes

CLIM 043

Frequency of updates

Updates are scheduled every 4 years

EEA Contact Info

Permalinks

Permalink to this version: 72fe62fd17ee495888699bc1d1573d35
Permalink to latest version: IND-349-en

Geographic coverage

Belgium Denmark France Germany Greece Ireland Italy Luxembourg Netherlands Portugal Spain United Kingdom Oahu Island (Hawaii, United States)

Temporal coverage

1998-2010

For references, please go to https://www.eea.europa.eu/data-and-maps/indicators/ocean-acidification/assessment or scan the QR code.

PDF generated on 25 Apr 2024, 01:01 AM

Dates

First draft created:

15 Nov 2012, 09:58 AM

Publish date:

20 Nov 2012, 03:32 PM

Last modified:

11 May 2021, 11:50 AM

Topics

Topics: Climate change adaptation Water and marine environment