NASA Greenland Mission Completes Six Years of Mapping Unknown Terrain
To learn how ocean water is melting glaciers, NASA’s Oceans Melting Greenland mission extensively surveyed the coastline of the world’s largest island.
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Warming Seas Are Accelerating Greenland’s Glacier Retreat
Scientists with NASA’s Oceans Melting Greenland mission are probing deep below the island’s warming coastal waters to help us better predict the rising seas of the future.
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Cold Water Currently Slowing Fastest Greenland Glacier
NASA research shows that Jakobshavn Glacier, which has been Greenland's fastest-flowing and fastest-thinning glacier for the last 20 years, has made an unexpected about-face.
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The Hunt for Better Climate Science
NASA scientists are mapping the loss of ice in Greenland, part of a cutting-edge effort to understand how warming oceans melt ice sheets — a key factor in improving uncertain forecasts for sea-level rise.
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OMG, the Water's Warm! NASA Study Solves Glacier Puzzle
A new NASA study explains why the Tracy and Heilprin glaciers, which flow side by side into Inglefield Gulf in northwest Greenland, are melting at radically different rates.
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Mission Complete!
NASA’s Oceans Melting Greenland (OMG) mission completes six years of oceanographic measurements revealing the ocean plays a strong role in Greenland’s ice loss.
NASA's OMG: Where the Water Meets the Ice
Join JPL scientist Josh Willis in this video as he and the NASA Oceans Melting Greenland (OMG) team work to understand the role that ocean water plays in melting Greenland’s glaciers. From the sky and the sea, NASA’s OMG mission gathers data on glaciers and water temperature all around Greenland as they try to get a better picture of global sea level rise.
Global sea level rise will be one of the major environmental challenges of the 21st Century. Oceans Melting Greenland (OMG) has paved the way for improved estimates of sea level rise by investigating the question: To what extent are the oceans melting Greenland’s ice from below? Over a six-year campaign, OMG measured changing water temperatures on the continental shelf surrounding Greenland, and how marine glaciers reacted to the presence of warm, salty Atlantic Water. OMG also facilitated improved measurements of the shape and depth of the sea floor because its complicated geometry steers currents and determines whether Atlantic Water can reach into the long narrow fjords to interact with the coastal glaciers.
Understanding Glaciers
A typical Greenland glacier reaches the water in a long fjord or canyon, where a layer of cold, fresh surface water sits above a deeper layer of warm, salty water. The video explains how the meltwater runs off at the bottom of the glacier and causes a plume which erodes the edge of the glacier. Temperature of the deep warm water layer is a key factor in how rapidly the plume will melt away the ice.
To measure changes in the deep layer of warm water around Greenland, OMG conducted an aircraft campaign each year in the summer to deploy 250 expendable temperature and salinity probes along the continental shelf. These measurements were matched with corresponding observations of the ice: OMG used NASA’s G-III to fly the Glacier and Ice Surface Topography Interferometer (GLISTIN-A) in order to generate high resolution, high precision elevation measurements of Greenland’s coastal glaciers during the spring. These annual surveys by GLISTIN-A were used to quantify the thinning and retreat of ice over each season. These data, along with fundamental new observations of the sea floor geometry, provided a revolutionary data set which is being used to understand Greenland’s ice loss, model ocean/ice interactions, and improve estimates of global sea level rise.