Global and European sea level

Trend in absolute sea level across Europe based on satellite measurements

Note: Horizontal spatial distribution of mean sea level trend in European Seas (January 1993- December 2015)

Data source:

• Time series of gridded Sea Level Anomalies (SL_cci v2.0) provided by European Space Agency (ESA)

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Trend in relative sea level at selected European tide gauge stations

Note:

Data source:

• Relative sea level trends (tide gauge data) provided by Permanent service for mean sea level (PSMSL)

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Projections for global mean sea level rise and its contributions

Note: Projections for global mean sea level rise and its contributions in 2081–2100 relative to 1986–2005 from process-based models for the four representative concentration pathways (RCPs) and emisions scenario SRES A1B used in the IPCC Fourth Assessment Report. The grey boxes show the median of the model projections (central bar) as well as the likely range, which comprises two thirds of the model projections. The coloured bars and boxes show estimates for the different contributions to global sea-level rise. For further information, see the source document.

Data source:

• Climate Change 2013: The Physical Science Basis provided by Intergovernmental Panel on Climate Change (IPCC)

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Projected change in relative sea level

Note: The map shows the projected change in relative sea level in 2081-2100 compared to 1986-2005 for the medium-low emission scenario RCP4.5 based on an ensemble of CMIP5 climate models. Projections consider land movement due to glacial isostatic adjustment but not land subsidence due to human activities. No projections are available for the Black Sea.

Data source:

• RCP4.5 total sea level rise projections provided by Integrated Climate Data Centre (ICDC)

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Past trends: global mean sea level

Sea level changes can be measured using tide gauges and remotely from space using satellite altimeters. Many tide gauge measurements have long multi-decade time series, with some exceeding more than 100 years. However, the results can be distorted by various regional and local effects, such as vertical land motion processes. Satellite altimeters enable absolute sea level to be measured from space and provide much better spatial coverage (except at high latitudes). However, the length of the altimeter record is limited to about 25 years.

Reconstructions of global mean sea level (GMSL) based on tide gauge observations suggest a rise of about 20 cm in the period between 1901 and 2015 (Figure 1). Global mean sea level in 2016 was the highest yearly average over the record. Reconstructions considered in the IPCC Fifth Assessment Report (AR5) estimate the rate of 20^th century sea level rise at 1.6 mm/year, with significant decadal variation (see green curve in Figure 1). This value is somewhat higher than the sum of the known contributions to sea level rise over this period. More recent reconstructions suggest a slightly lower rate of 20^th century sea level rise, at about 1.2 mm/year (see red curve in Figure 1) [i].

Estimates for the rate of GMSL rise during the period since 1993, for which satellite-based measurements are available, are considerably higher than the 20th century trend, at 2.4–3.2 mm/year (see dark blue curve in Figure 1). Different statistical methods for assessing sea level trends and changes therein can come to somewhat different conclusions, but all available assessments agree that an acceleration in the rate of GMSL rise since the early 1990s is detectable [ii]. If the lower estimates regarding 20^th century sea level rise (shown in the red curve in Figure 1) were confirmed, the acceleration since the 1990s would be even more pronounced.

The causes of GMSL rise over recent decades are now reasonably well understood. Thermal expansion and melting of glaciers account for around 75 % of the measured sea level rise since 1971. The contribution from melting of the Greenland and Antarctic ice sheets has increased since the early 1990s. Changes in land water storage have made only a small contribution, but the rate of groundwater extraction has increased recently and now exceeds the rate of storage in reservoirs [iii]. A recent study concludes that climate-driven variability in precipitation has resulted in increased water storage on land, and that global sea level rise in the period 2002–2014 would have been 15–20 % higher in the absence of this climate variability [iv].

Evidence from formal detection and attribution studies showing that most of the observed increase in GMSL since the 1950s can be attributed to anthropogenic climate change has increased since the publication of the IPCC AR5 [v].

Past trends: mean sea level along the European coastline

Sea level measurements for the European region are available from satellite altimeter observations (Figure 2) and from tide gauges (Figure 3). Satellite observations, which show changes in absolute sea level, are available from 1993. Tide gauge records can be more than 100 years long; they show changes in relative sea level considering also land changes, which is more relevant for coastal protection than absolute sea level. Most European coastal regions experience increases in both absolute and relative sea level, but there are sizeable differences between the rates of absolute and relative sea level change across Europe.

Figure 2 shows linear trends in absolute sea level from 1992 to 2015 as observed by satellites. The main differences between regional seas and basins are primarily the result of different physical processes being the dominant cause of sea level change at different locations. For instance, the Mediterranean Sea is a semi-closed, very deep basin, exchanging water with the Atlantic Ocean through only the narrow Gibraltar Strait. Salinity in the Mediterranean Sea may increase in the future and this will tend to offset rises in sea level due to thermal expansion from warming. The NAO, interannual wind variability, changes in ocean circulation patterns, and the location of large-scale gyres and small-scale eddies are further factors that can influence local sea level in the European seas. Obviously, sea level changes in coastal zones are most relevant for society.

Figure 3 shows linear trends in relative sea level from 1970 to 2015 as observed by tide gauge stations in Europe. These trends can differ from those measured by satellites because of the longer time period covered and because tide gauge measurements are influenced by vertical land movement whereas satellite measurements are not. In particular, since the last ice age, the lands around the northern Baltic Sea have been, and are still, rising owing to the post-glacial rebound [vi].

Projections: global mean sea level

The main approach to projecting future sea level are process-based models, which are rooted in state-of-the-art climate model simulations. A significant recent step forwards in projecting future sea levels is the improved understanding of the contributing factors to recently observed sea level rise, which has increased confidence in the use of process-based models for projecting the future.

The IPCC AR5 concluded that the rate of GMSL rise during the 21st century will very likely exceed the rate observed in the period 1971–2010 for all emissions scenarios. Process-based models estimate the rise in GMSL for the period 2081–2100, compared with 1986–2005, to be likely in the range of 0.26–0.54 m for RCP2.6, 0.32–0.62 m for RCP4.5, 0.33–0.62 m for RCP6.0 and 0.45–0.81 m for RCP8.5. For RCP8.5, the rise in GMSL by 2100 is projected to be in the range of 0.53–0.97 m, with a rate during 2081–2100 of 7–15 mm/year (Figure 4). A collapse of marine-based sectors of the Antarctic Ice Sheet (i.e. those areas where the bed lies well below sea level and the edges flow into floating ice shelves) could cause GMSL to rise substantially above the likely range projected for the 21st century, but the evidence is insufficient for estimating the likelihood of such a collapse [vii].

Some recent studies highlight the contributions to recent sea level rise from ice sheet mass loss that were not included in the process-based models underlying the AR5 estimates above [viii]. A broad expert assessment of future sea level rise resulted in higher estimates than those from the process-based models reviewed in the AR5. The best expert estimates for sea level rise during the 21st century were 0.4–0.6 m for the low forcing scenario (RCP2.6) and 0.7–1.2 m for the high forcing scenario (RCP8.5) [ix]. Similar results were derived in other recent studies [x]. A study that combined the model-based assessments from the AR5 with updated models and probabilistic expert assessment of the sea level contributions from the Greenland and Antarctic ice sheets suggests an upper limit for GMSL rise during the 21st century of 1.8 m, which has a 5 % probability of being exceeded under the RCP8.5 forcing scenario [xi]. Various national reports have used values in the range of 1.5–2.5 m as upper estimates for GMSL rise during the 21st century [xii]. One recent study suggests that ice sheet melting in Antarctica and Greenland could occur much faster than previously thought and may result in sea level rise of several metres during the 21st century [xiii], but these findings have been controversial. While these high-end scenarios are somewhat speculative, their consideration is nevertheless important for long-term coastal risk management, in particular in densely populated coastal zones [xiv].

Sea level rise will continue to rise far beyond 2100. A recent effort to synthesise process-based model projections using a physically-based emulator suggests global sea level rise at 2300 of 0.8–1.4 m for RCP2.6, 1.3–2.3 m for RCP4.5, 1.7–3.2 m for RCP6.0 and 3.4–6.8 m for RCP8.5 [xv]. However, another recent modelling study suggests that ice loss from Antarctica could occur more rapidly than previously thought and lead to sea level rise of more than 15 m by 2500 under the RCP8.5 emissions scenario [xvi]. On a multi-millennial time scale, projections based on process-based models suggest a quasi-linear GMSL rise of 1–3 m per degree of global warming for sustained warming over a period of 2 000 years. Significantly higher estimates for GMSL rise on multi-millennial time scales, of up to 50 m over 10 000 years for a high emissions scenario, have been derived from the geological record [xvii].

Projections: mean sea level along the European coastline

Regional and local sea levels differ from the global mean owing to large-scale factors such as non-uniform changes in ocean density and changes in ocean circulation. Furthermore, disintegrating land-ice affects sea level differentially because of gravitational effects and the viscoelastic response of the lithosphere [xviii]. Sea level is also affected by local and regional factors, such as vertical land movement. While there remains considerable uncertainty in the spatial patterns of future sea level rise, around 70 % of the world’s coastlines are expected to experience a local mean sea level change within ±20 % of the projected GMSL change [xix].

Relative sea level change along most of the European coastline is projected to be reasonably similar to the global average. The main exceptions are the northern Baltic Sea and the northern Atlantic coast, which are experiencing considerable land rise as a consequence of post-glacial rebound and changes in the gravity field of the Greenland ice sheet. As a result, sea level relative to land is rising slower than elsewhere in these regions or may even decrease (Figure 5) [xx].

A probabilistic assessment of regional sea-level rise in northern and central Europe estimated relative sea level change during the 21st century for the high RCP8.5 emissions scenario from –14 cm (in Luleå, northern Sweden) to 84 cm in Den Helder (Netherlands); high estimates (with a 5 % probability to be exceeded) range from 52 cm to 181 cm, respectively [xxi]. Making regional projections for relatively small isolated and semi-closed ocean basins, such as the Mediterranean or the Baltic, is even more difficult than for the open ocean.

Change in the frequency of flooding events under projected sea level rise

Note: This map shows the estimated multiplication factor, by which the frequency of flooding events of a given height changes between 2010 and 2100 due to projected regional sea relative level rise under the RCP4.5 scenario. Values larger than 1 indicate an increase in flooding frequency

Data source:

• Summary of AR5 regional projections and allowances provided by Antarctic Climate & Ecosystems Cooperative Research Centre

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Past trends: extreme sea level along the European coastline

Producing a clear picture of either past changes or future projections of extreme high water levels for the entire European coastline is a challenging task because of the impact of local topographical features on surge events. While there are numerous studies for the North Sea coastline, fewer are available for the Mediterranean Sea and the Baltic Sea, although this situation is starting to improve.

Extreme sea levels show pronounced short- and long-term variability. A recent review of extreme sea level trends along European coasts concluded that long-term trends are mostly associated with the corresponding mean sea level changes. Changes in wave and storm surge climate mostly contribute to interannual and decadal variability, but do not show substantial long-term trends [i]. When the contribution from local mean sea level changes and variations in tide are removed from the recent trends, the remaining effects of changes in storminess on extreme sea level are much smaller or even no longer detectable [ii]. Additional studies are available for some European coastal locations, but these typically focus on more limited spatial scales [iii]. The only region where significant increases in storm surge height were found during the 20th century is the Estonian coast of the Baltic Sea [iv].

In conclusion, while there have been detectable changes in extreme water levels around the European coastline, most of these are the result of changes in local mean sea level. The contribution from changes in storminess is currently small in most European locations and there is little evidence that any trends can be separated from long-term natural variability.

Projections: extreme sea level at the European coastline

Future projections of extreme sea level can be made using either process-based (dynamic) or empirical statistical modelling of storm surge behaviour driven by the output of global climate models [v]. Uncertainty in these projections for Europe remains high and is ultimately linked to the uncertainty in future mid-latitude storminess changes. This is an area where current scientific understanding is advancing quickly, as climate model representations of aspects of Northern Hemisphere storm track behaviour are showing improvements associated with, for instance, greater ocean and atmosphere resolution. However, the newest global climate models have not yet, typically, been downscaled to suitably fine scales and used in studies of future storm surges [vi].

The current research evidence suggests that projected increases in extreme sea level along the European coast during the upcoming decades will mostly be the result of mean sea level changes [vii]. However, several recent studies suggest that changes in wave and storm surge climate may also play a substantial role in sea level changes during the 21st century in some regions. These studies project an increase in storm surge level for most scenarios and return periods along the northern European coastline, which can exceed 30 % of the relative sea level rise under the RCP8.5 scenario. Storm surge levels along most European coastal areas south of 50 °N showed small changes and in some regions may decline to partly offset the effect of mean sea level rise on projected extreme water levels [viii]. Sea level rise may also change extreme water levels by altering the tidal range and local wave climate. Tidal behaviour is particularly responsive in resonant areas of the Bristol Channel and the Gulf of Saint-Malo and in the south-eastern German Bight and Dutch Wadden Sea [ix].

A 10 cm rise in sea level typically causes an increase by about a factor of three in the frequency of flooding to a given height. The frequency of flooding events is estimated to increase by more than a factor of 10 in many European locations, and by a factor of more than 100 in some locations (Figure 6) for the RCP4.5 scenario [x]. Large changes in flood frequency mean that what is an extreme event today may become the norm by the end of the century in some locations.

Sea level rise substantially increases the risk of coastal flooding, which affects people, communities and infrastructure. The ClimateCost and PESETA II projects have estimated that a 30 cm sea level rise by the end of the 21st century, in the absence of public adaptation, would more than triple annual damages from coastal floods in the EU from EUR 5 to 17 billion [xi]. Another recent study has estimated the economic damage risk from coastal flooding in the main coastal cities in Europe to increase by a factor of about 40 from 2030 and 2100 under the RCP8.5 scenario, in the absence of adaptation  [xii].

The potential impacts from coastal flooding can be substantially reduced by timely adaptation measures, but they are associated with significant costs [xiii]. For any particular location, it is important to look in detail at the change in the height of flood defences that might be required. Where the flood frequency curve is very flat, modest increases in flood defences might be sufficient. Where the flood frequency curve is steeper, larger increases in protection height or alternative adaptation, including managed retreat, might be needed.