{"id":346139,"date":"2024-10-09T15:47:27","date_gmt":"2024-10-09T13:47:27","guid":{"rendered":"https:\/\/climatescience.press\/?p=346139"},"modified":"2024-10-09T15:47:29","modified_gmt":"2024-10-09T13:47:29","slug":"heat-transfer-and-meltwater-flows-in-ice-sheets","status":"publish","type":"post","link":"https:\/\/climatescience.press\/?p=346139","title":{"rendered":"Heat transfer and meltwater flows in ice sheets"},"content":{"rendered":"\n
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TOPSHOT – Meltwater flows from the Greenland ice sheet into the Baffin Bay near Pituffik, Greenland on July 17, 2022 as captured from the ground during a NASA mission along with University of texas scientists to measure melting Arctic sea ice. – New observations from ICESAT-2 show remarkable Arctic Sea ice thinning in just three years. Over the past two decades, the Arctic has lost about one-third of its winter sea ice volume, largely due to a decline in sea ice that persists over several years, called multiyear ice, according to a new study. The study also found sea ice is likely thinner than previous estimates. (Photo by Kerem Y\u00fccel \/ AFP) \/ The erroneous mention appearing in the metadata of this photo by Kerem Y\u00fccel has been modified in AFP systems in the following manner: [as captured from the ground] instead of [during an airborne mission]. Please immediately remove the erroneous mention from all your online services and delete it from your servers. If you have been authorized by AFP to distribute it to third parties, please ensure that the same actions are carried out by them. Failure to promptly comply with these instructions will entail liability on your part for any continued or post notification usage. Therefore we thank you very much for all your attention and prompt action. We are sorry for the inconvenience this notification may cause and remain at your disposal for any further information you may require. (Photo by KEREM YUCEL\/AFP via Getty Images)<\/figcaption><\/figure>\n\n\n\n

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From Climate Etc. <\/a><\/p>\n\n\n\n

by Dan Hughes<\/p>\n\n\n\n

This post challenges the conventional framework for simulating meltwater flows on glaciers and ice sheets.<\/p>\n\n\n\n

Increased melting rates due to potential increases in temperature would add liquid water directly into the oceans. An additional aspect is that the meltwater, on reaching the base of glaciers, might lead to increased sliding of the glaciers and the consequent calving at the terminus.<\/p>\n\n\n\n

The World Resources Institute (WRI) has summarized <\/a>the IPCC AR6 results regarding melting of Greenland and Antarctica ice:<\/p>\n\n\n\n

Should warming reach between 2 degrees C (3.6 degrees F) and 3 degrees C (5.4 degrees F), for example, the West Antarctic and Greenland ice sheets could melt almost completely and irreversibly over many thousands of years, causing sea levels to rise by several meters.<\/em><\/p>\n\n\n\n

Temperature Increase<\/em><\/td>1.5 C (2.7 F)<\/em><\/td>2.0 C (3.6 F)<\/em><\/td>3.0 C (5.4 F)<\/em><\/td><\/tr>
Global mean sea level rise by 2100<\/em><\/td>0.28 \u2013 0.55 m<\/em>(0.92 \u2013 1.80 ft)<\/td>0.33 \u2013 0.61 m<\/em>(1.08 \u2013 2.00 ft)<\/td>0.44 \u2013 0.76 m<\/em>(1.44 \u2013 2.40 ft)<\/td><\/tr><\/tbody><\/table><\/figure>\n\n\n\n

Meltwater flows on the surface of and with glaciers and other ice sheets are important relative to the addition of liquid water into Earth\u2019s oceans, and to bulk motions of the glaciers and ice sheets. Glacial meltwater might flow along the surface like a stream or river, accumulate in surface lakes, flow downward into open crevasses or moulins, accumulate as lakes interior to the ice mass, flow as a sheet of liquid between the ice bottom and bedrock, or flow enclosed in channels partially or completely embedded within the ice mass.<\/p>\n\n\n\n

Flows that reach the boundary of the ice sheet deplete the ice mass balance and can contribute to sea level rise if the flow reaches the sea.  Meltwater remaining on the surface of the glacier or ice sheet can refreeze and have no impact on the glacier mass balance.  Flows reaching the base of the glaciers by way of crevasse and moulins are considered to provide potential lubrication and flotation that enhances bulk ice motions.<\/p>\n\n\n\n

How solid is the foundation for simulating glacial meltwater flows that are included in projections of ice sheet melting?<\/p>\n\n\n\n

Glacial meltwater flows have been modeled for more than four decades using thermal-hydraulic modeling.  The widely used Springer-Hutton formulation is based on principles of continuum mechanics, and detailed mathematical reduction to the standard 1-dimensional channel- average form for engineering applications. A steady-state energy balance equation is applied to flow of liquid water in ice channels embedded in large ice masses. The Spring-Hutter system considers the case of evolution in time and space of the flow area of the channel. Changes in flow area are caused by ice melting and dynamics of the ice in which channels are located. There have been numerous studies providing clarifications, modifications and applications of Spring-Sutter framework.<\/p>\n\n\n\n

New paper<\/strong><\/p>\n\n\n\n

I have conducted a detailed analysis of the Spring-Sutter equations and their solutions in this paper [EDHmelt]<\/a><\/p>\n\n\n\n

The paper clarifies and improves calculations of the role of viscous dissipation of kinetic energy into thermal energy as this physical process appears in models of meltwater flows embedded in and at the boundaries of glaciers and ice sheets.<\/p>\n\n\n\n

Meltwater flows on the surface of and within glaciers and other ice sheets are important relative to the addition of liquid water into Earth\u2019s oceans, and to bulk motions of the glaciers and ice sheets. Glacial meltwater might flow along the surface like a stream or river, accumulate in surface lakes, flow downward into open crevasses or moulins, accumulate as lakes interior to the ice mass, flow as a sheet of liquid between the ice bottom and bedrock, or flow enclosed in channels partially or completely embedded within the ice mass.<\/p>\n\n\n\n

Flows that reach the boundary of the ice sheet deplete the ice mass balance and can contribute to sea level rise if the flow reaches the sea.  Meltwater remaining on the surface of the glacier or ice sheet can refreeze and have no impact on the glacier mass balance.  Flows reaching the base of the glaciers by way of crevasse and moulins are considered to provide potential lubrication and flotation that enhances bulk ice motions.<\/p>\n\n\n\n

A dimensionless form for steady-state energy balance for the liquid, accounting for effects of meltwater on the bulk liquid, is developed and solved. Analytical solutions of the temperature distribution along the channel are developed. The solutions explicitly illustrate effects of viscous dissipation of kinetic energy into heat, and the consequence effects on melting ice at the liquid-ice interface.<\/p>\n\n\n\n

The paper shows that:<\/p>\n\n\n\n