Message

Rate this item
(0 votes)

Greenland ice sheet collapse

Main Contributors:

Juan Carlos Rocha, Rolands Sadauskis

Other Contributors:

Reinette (Oonsie) Biggs, Garry Peterson

Summary

The great ice sheet of Greenland was, traditionally, believed to take thousands of years to respond to external forcing. Recent observations suggest, however, that major changes in the dynamics of parts of the ice sheet are taking place over large timescales. Widespread thinning at rates generally exceeding those are expected to occur due to recent warmer summers as the atmospheric temperatures are rising. The main identified direct driver behind the loss of ice sheet volume is a warming atmosphere and ocean, which is driven by human greenhouse gas emissions.  There are two feedback mechanisms that are maintaining the current regime of the system: an ice-albedo mechanism and meltwater-ice sliding mechanism. The main mechanisms to reduce the risks of this regime shift are to halt global human greenhouse gas emissions and decrease atmosphere concentrations of greenhouse gases.  This regime shift is very difficult to reverse over decadal time scales.

 

Drivers

Key direct drivers

  • Global climate change

Land use

  • Land use impacts are primarily off-site (e.g. dead zones)

Impacts

Ecosystem type

  • Rock and Ice
  • Planetary

Key Ecosystem Processes

  • Water cycling

Biodiversity

  • Biodiversity

Provisioning services

  • Fisheries
  • Wild animal and plant foods

Regulating services

  • Climate regulation
  • Water regulation

Cultural services

  • Recreation
  • Aesthetic values
  • Knowledge and educational values
  • Spiritual and religious

Human Well-being

  • Livelihoods and economic activity
  • Security of housing & infrastructure
  • Cultural, aesthetic and recreational values
  • Social conflict
  • Cultural identity

Key Attributes

Typical spatial scale

  • Sub-continental/regional

Typical time scale

  • Centuries

Reversibility

  • Unknown

Evidence

  • Models
  • Paleo-observation
  • Contemporary observations

Confidence: Existence of RS

  • Contested – Reasonable evidence both for and against the existence of RS

Confidence: Mechanism underlying RS

  • Well established – Wide agreement on the underlying mechanism

Links to other regime shifts

Alternate regimes

The Greenland Ice Sheet (GIS) is approximately 1.7 million km2 in areas covering approximately 80%  of Greenland. It is grounded on bedrock that mostly rests near or above sea level thus would contribute to the globally averaged sea-level rise of 7.3 m if melted completely (Parizek et al. 2004, Lemke et al. 2007).  Anticipated future climate warming has the potential to permanently reduce large areas of GIS or even abate it completely. The evidence suggests nearly total ice-sheet loss may result from warming of more than a few degrees above mean 20th century values, but this threshold is poorly defined (perhaps as little as 2oC or more than 7oC) (Alley et al. 2010).

Greenland with permanent ice sheet

This regime can be described as permanent ice body cover over major parts (~80%) of Greenland only exposing the bedrock in western and southern parts. The Greenland Ice Sheet has been more closely tied to temperature than to anything else. It shrinks with warming and grows with cooling, thus the volume and cover vary throughout the seasons, but in case of cold climate the relationship between the ice growth/decline would be approximately evenly balanced or with a slightly increased ice growth. In winter when the atmospheric temperatures decrease below freezing point and precipitation levels decline, the accumulation of the ice steadily increases (Bamber et al. 2007).

Greenland without permanent ice sheet

Due to the loss of the ice-sheet volume as a result of the warming, Greenland territory in future could become free from permanent ice sheet cover. This would happen as a consequence of the negative relation to ice growth/ice decline during the winter and summer where the lost ice volume in summer could not be reproduced in the following winter. Rising sea level as a result of warming tends to float marginal regions of ice sheets and force further retreat, so the generally positive relation between sea level and temperature means that typically both reduce the volume of the ice sheet (Alley et al. 2010).

Drivers and causes of the regime shift

Increasing greenhouse gas concentration from anthropogenic sources is predicted to cause a rise in global mean temperatures (Cubasch et al. 2001). One of the most common anthropogenic greenhouse gases is carbon dioxide (CO2). The influence of this driver is well established as confirmed by many studies. The indirect driver that is increasing anthropogenic CO2 levels in atmosphere is the burning of fossil fuels such as coal and natural gas. It is occurring regionally but has global impact and is well established in literature.

How the regime shift works

The initial regime would typically occur in cold climate conditions where the relationship between the ice growth/decline would be approximately evenly balanced or with a slightly increased ice growth. The two main mechanisms that maintain this regime are ice-albedo mechanism and meltwater-ice sliding mechanism.

Increasing CO2 levels in atmosphere - the key driver of the regime shift, initiates the increase of atmospheric temperatures and changes in albedo. As a result - increased absorption of solar energy promotes higher air, ice, water and land temperatures which leads towards degrading sea ice. Also the inland surface temperature increase can cause surface melting in the ablation zone that presently accounts for roughly half of the mass loss from the GIS (Parizek et al. 2004). Thus this driver indirectly is increasing drainage of meltwater feeding into crevasses close to the glacier margin resulting in higher calving rates (Murray et al. 2010). Furthermore, thinning and retreating of the glacier tongue due to these increased rates cause reduced effective pressures beneath the glacier, promoting faster flow that results in decrease of ice volume.  

The increase in surface air temperatures changes the ice-albedo feedback thermodynamics. This means that the heat exchange within the sea ice, as well as between the top and bottom of the ice is changed. This leads to a decrease in sea ice volume. The resulting increased amount of open land and water surface in summer decreases the albedo, as the dark ocean surface absorbs more solar radiation (Lindsay et al. 2005).  The annually integrated absorption of solar radiation is observed to increase when the surface albedo is relatively low (Rigor et al. 2002, Holland et al. 2006). This increasingly accumulated amount of heat on the surface reinforces the initial warming. Due to the loss of the ice-sheet volume as a result of the warming, Greenland territory in future could become free from permanent ice sheet cover. This would happen as a consequence of the negative relation to ice growth/ice decline during the winter and summer where the lost ice volume in summer could not be reproduced in the following winter. The Greenland without permanent ice sheet regime is characterized by other dominant feedback mechanisms. For example ice volume-wave action, the water temperature-density and meltwater-ice sliding velocity mechanisms.

Impacts on ecosystem services and human well-being

The shift to the regime of Greenland without ice sheet will mainly result in loss of some desirable ecosystem services. The ecosystem service of desirable climate regulation could be lost as the change in movement of currents (change in thermohaline circulation) and air masses would alter the transport of heat. This could lead to increased hurricane activity, a southward shift of tropical rainfall belts with resulting agricultural impacts, and disruptions to marine ecosystems.

The loss of certain animal and plant food species as provisioning services is predicted in the future. These changes may have important consequences for food webs and could well be extremely significant for the Greenland economy, which is highly dependent on fisheries (AMAP 2007). Such cultural services like recreation and aesthetical values would also be affected. Each of those services attracts more people to see the Ice sheet thus also bringing in more tourists. Water regulation as regulating ecosystem services could be altered through the large input of freshwater in the water cycle.  The vast amount of "stored" water entering the water cycle within warmer climate would result in severe winter precipitation.

A new ecosystem service is possible as the thawing ice sheet will potentially form glacial freshwater lakes in Greenland. This will generate new recreation opportunities in summer – using lakes for different purposes from different social groups. Flora could expand deeper into Greenland and new species could be introduced as the climate warms giving the local population the chance to gain additional plant foods.

Management options

The potential options for preventing or reversing this potential regime shift mainly relates to the decrease of greenhouse gas input into the atmosphere at a global scale. This has to be achieved in order to prevent further climate warming leading to the loss of Greenland Ice Sheets. Options include reduction of deforestation, use of fossil fuels and charcoal as energy source, and cleaner economies. Geoengineering strategies has also been proposed, large scale experiments to decrease global temperature and CO2 concentration in the atmosphere. However, their applicability is debated and the usefulness is contested. As this system boundaries are set mainly around geophysical variables it is necessary to look at the social mechanisms involved to limit the influence on the main direct driver of greenhouse gas emissions. Nevertheless even if CO2 levels in atmosphere leads to atmospheric temperature increase, it is very hard to achieve from the local to regional management perspective. It does require global coordination and cooperation in order to achieve CO2 reduction targets.

Key References

  1. Alley RB, Andrews JT, Brigham-Grette J, Clarke GKC, Cuffey KM, Fitzpatrick JJ, Funder S, Marshall SJ, Miller GH, Mitrovica JX, Muhs DR, Otto-Bliesner BL, Polyak L, White JWC. 2010. History of the Greenland Ice Sheet: paleoclimatic insights. Quaternary Science Reviews 29,1728-1756.
  2. AMAP. 2009. Summary – The Greenland Ice Sheet in a Changing Climate: Snow, Water, Ice and Permafrost in the Arctic (SWIPA). Arctic Monitoring and Assessment Programme (AMAP). Oslo. 22 pp.
  3. Bamber JL, Alley RB, Joughin I. 2007. Rapid response of modern day ice sheets to external forcing. Earth and Planetary Science Letters 257,1-13.
  4. Bell RE. 2008. The role of subglacial water in ice-sheet mass balance. Nat Geosci 1,297–304.
  5. Cubasch U. et al. 2001. Projections of future climate change. Climate Change 2001: The Scientific Basis, J. T. Houghton et al., Eds., Cambridge University Press. 525–582.
  6. Cuffey KM, Marshall SJ. 2000. Substantial contribution to sealevel rise during the last interglacial fromthe Greenland ice sheet. Nature 404, 591–594.
  7. Gregory JM, Huybrects P, Raper SCB. 2004. Threatened loss of the Greenland ice-sheet. Nature 428, 616.
  8. Holland MM, Bitz CM, and Tremblay B. 2006. Future abrupt reductions in the summer Arctic sea ice. Geophys. Res. Lett. 33.
  9. IPCC 2007. Climate Change 2007: The Physical Science Basis. Cambridge University Press, New York.
  10. Krabill W. et al. 2004. Greenland ice sheet: Increased coastal thinning. Geophys. Res. Lett. 31.
  11. Le Quere C, Takahashi T, Buitenhuis ET, Rodenbeck C, Sutherland SC. 2010. Impact of climate change and variability on the global oceanic sink of CO2. Global Biogeochemical Cycles 24.
  12. Lemke P, Ren J, Alley RB, Allison I, Carrasco J, Flato G, Fujii Y, Kaser G, Mote P, Thomas RH, Zhang T. 2007. Observations: changes in snow, ice and frozen ground. In: Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL. (Eds.), Climate Change 2007: The Physical Science Basis. Contribution ofWorking Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge and New York. 996 pp.
  13. Murray T, Scharrer K, James TD, Dye SR, Hanna E, Booth AD, Selmes N, Luckman A, Hughes ALC, Cook S, Huybrechts P. 2010. Ocean regulation hypothesis for glacier dynamics in southeast Greenland and implications for ice sheet mass changes. Journal of Geophysical Research 115.
  14. Nick MF, Vieli A, Howat IM, Joughin I. 2009. Large-scale changes in Greenland outlet glacier dynamics triggered at the terminus. Nature Geoscience 2, 110-114.
  15. Otterå OH, Drange H, Bentsen M, Kvamstø NG, Jiang D. 2004. Transient response of the Atlantic meridional overturning circulation to enhanced freshwater input to the Nordic Seas-Arctic Ocean in the Bergen Climate Model. Tellus 56A, 342-361.
  16. Parizek BR, and Alley RB. 2004. Implications of increased Greenland surface melt under global-warming scenarios: Ice-sheet simulations. Quat. Sci. Rev. 23,1013-1027.
  17. Rahmstorf S. 2000. The thermohaline ocean circulation—A system with dangerous thresholds? Clim. Change 46,247–256.
  18. Rigor IG, Wallace JM, and Colony RL. 2002. Response of sea ice to the Arctic Oscillation. J. Climate 15,2648–2668.
  19. Vizcaino M, Mikolajewicz U, Groger M, Maier-Reimer E, Schurgers G, and Winguth A. 2008. Long-term ice sheet-climate interactions under anthropogenic greenhouse forcing simulated with a complex Earth System Model. Clim. Dynam. 31,665– 690.
  20. Zhang X, and Walsh JE. 2006. Towards a seasonally ice-covered Arctic Ocean: Scenarios from the IPCC AR4 simulations. Journal of Climate 19,1730– 1747.

Citation

Juan Carlos Rocha, Rolands Sadauskis, Reinette (Oonsie) Biggs, Garry Peterson. Greenland ice sheet collapse. In: Regime Shifts Database, www.regimeshifts.org. Last revised 2017-08-28 19:50:00 GMT.
Read 25020 times
Login to post comments