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Sea level rise (Rev #12, changes)

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One among the expected side effects of global warming is a global increase in sea level, or sea level rise. Sea levels are expected to increase for a number of reasons, including melting ice and the fact that warmer water occupies a greater volume. This is expected to affect low-lying land areas along coasts, including river deltas and barrier islands.

Sea levels have varied substantially over time. The CSIRO report on Historical sea level changes includes this graph.


According to the NRC climate stabilization targets report, global sea level has risen by about 0.2 meters since 1870. The sea level rise by 2100 is expected to be at least 0.6 meters due to thermal expansion and loss of ice from glaciers and small ice caps. This could be enough to permanently displace as many as 3 million people — and raise the risk of floods for many millions more.

Ice loss is also occurring in parts of Greenland and Antarctica. If all the ice in Greenland were to melt, it would cause an additional sea level rise of 7.2 meters, and if all the ice in the West Antarctic Ice Sheet were to melt, it would cause a further rise of 4.8 meters (see below). However, the amount of sea level rise in the next century remain uncertain, because the rate of melting of these bodies of ice is hard to predict.

Note: Due to the Archimedes’ principle the meltdown of ice that is freely floating will not increase the sea level. Therefore all estimates need to include ice residing on land only. See also:


If the entire 2.8510 62.85 \cdot 10^6 km3 of ice in Greenland were to melt, it would lead to a global sea level rise of 7.2 m. This would inundate most of the world’s coastal cities and remove several small island countries from the face of the Earth, since island nations such as Tuvalu and Maldives have a maximum altitude below or just above this level:


It is estimated that the volume of the Antarctic ice sheet is about 2.5410 72.54 \cdot 10^7 km3. The weight of the ice has caused the underlying rock to sink by between 0.5 and 1 kilometers.

The West Antarctic Ice Sheet (or WAIS) contains just under 10% of this, or 2.210 62.2 \cdot 10^6 km3:

  • Matthew B. Lythe and David G. Vaughan, BEDMAP: A new ice thickness and subglacial topographic model of Antarctica, Journal of Geophysical Research 106 (June 2001), 11335–11352.

Large parts of the West Antarctic Ice Sheet (or WAIS) sit on a bed which is below sea level and slopes downward inland. This slope, and the low isostatic head, mean that the ice sheet is theoretically unstable: a small retreat could in theory destabilize the entire WAIS leading to rapid disintegration. However, current computer models do not include the physics necessary to simulate this process, and observations do not provide guidance, so predictions as to its rate of retreat remain uncertain.

In January 2006, in a UK government-commissioned report, the head of the British Antarctic Survey, Chris Rapley, warned that this huge west Antarctic ice sheet may be starting to disintegrate. Rapley said a previous Intergovernmental Panel on Climate Change (IPCC) report that played down the worries of the ice sheet’s stability should be revised. “The last IPCC report characterized Antarctica as a slumbering giant in terms of climate change,” he wrote. “I would say it is now an awakened giant. There is real concern.”

(Note that the IPCC report did not use the words “slumbering giant”.)

Rapley said, “Parts of the Antarctic ice sheet that rest on bedrock below sea level have begun to discharge ice fast enough to make a significant contribution to sea level rise. Understanding the reason for this change is urgent in order to be able to predict how much ice may ultimately be discharged and over what timescale. Current computer models do not include the effect of liquid water on ice sheet sliding and flow, and so provide only conservative estimates of future behaviour.”

It has been argued that a collapse of the WAIS could raise global sea levels by approximately 3.3 meters:

  • J. L. Bamber, R.E.M. Riva, B.L.A. Vermeersen and A.M. LeBroq, Reassessment of the potential sea-level rise from a collapse of the West Antarctic Ice Sheet, Science 324 (2009), 901.

However, these authors claim there would be important regional variations, with the maximum increase concentrated along the Pacific and Atlantic seaboard of the United States, where the value is about 25% greater than the global mean, even for the case of a partial collapse.

If the entire West Antarctic Ice Sheet were to melt, this would contribute 4.8 m to global sea level:

  • J. L. Bamber, R.E.M. Riva, B.L.A. Vermeersen and A.M. LeBroq,, Reassessment of the potential sea-level rise from a collapse of the West Antarctic Ice Sheet (supporting online material), Science 324 (2009), 901.

  • Rob Young, Orrin Pilkey, How High Will Seas Rise? Get Ready for Seven Feet, Yale Environment 360, 14 Jan 2010.

Indications that the West Antarctic Ice Sheet is losing mass at an increasing rate come from the Amundsen Sea sector, and three glaciers in particular: the Pine Island, Thwaites and Smith Glaciers:

Data reveals they are losing more ice than is being replaced by snowfall. Total ice discharge from these glaciers increased 30% in 12 recent years, and the net mass loss increased 170% from 39 ± 15 Gt/yr to 105 ± 27 Gt/yr. The melting of these three glaciers alone is now contributing an estimated 0.24 millimetres per year to the rise in the worldwide sea level (see the article by Jenny Hogan above).

More generally, there has been substantial increase in Antarctic ice mass loss in the ten years 1996-2006, with glacier acceleration a primary cause:

In 1996 the net mass loss was 78 ± 78 gigatons/year. By 2006 this had risen to 153 ± 78 gigatons/year.


The CSIRO or Commonwealth Scientific and Industrial Research Organisation of Australia has a project on sea level changes. Their report on Historical sea level changes is on our recommended reading list.

Here is some research from their project on sea levels:


Research by Australian climate scientists has shown that global sea level has been rising at an increasing rate over the past 130 years. Using information from tide gauges and measurements from satellites, Dr John Church and Dr Neil White estimated changes in global mean sea levels since 1870.

Their work, published in the science journal Geophysical Research Letters (6 January), indicates an acceleration in the rate of sea-level rise that had not been detected previously.

‘Although predicted by models, this is the first time a 20th century acceleration has actually been detected,’ Dr Church says. ‘Our research provides added confidence in sea-level rise projections published by the Intergovernmental Panel on Climate Change Third Assessment Report.

‘If the acceleration over the past 130 year period continues, we would expect sea level to be 280-340mm above its 1990 levels by 2100. This is consistent with the projections in the Intergovernmental Panel on Climate Change Third Assessment Report.’

The Copenhagen Diagnosis

The Copenhagen Diagnosis, written in 2009, was intended to serve as an interim evaluation of the evolving science before the 5th IPCC report, which is not due for completion until 2013. Its executive summary says, among other things:

Current sea-level rise underestimates: Satellites show great global average sea-level rise (3.4 mm/yr over the past 15 years) to be 80% above past IPCC predictions. This acceleration in sea-level rise is consistent with a doubling in contribution from melting of glaciers, ice caps and the Greenland and West- Antarctic ice-sheets.

Sea-level prediction revised: By 2100, global sea-level is likely to rise at least twice as much as projected by Working Group 1 of the IPCC AR4, for unmitigated emissions it may well exceed 1 meter. The upper limit has been estimated as 2 meters sea-level rise by 2100. Sea-level will continue to rise for centuries after global temperature have been stabilized and several meters of sea level rise must be expected over the next few centuries.


How much sea level rise should we expect from Greenland and the West Antarctic Ice Sheet within the next, say, 10 years?

What are the best adaptive measures? Floating cities?

Has there been a time in history when the sea level was significantly higher than today?


category: climate