REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET

Climate and altitude are the primary drivers in the distribution of snow facies, ice facies and zones on the surface of the Greenland Ice Sheet. There are three different facies: ablation, percolation, and dry-snow, and two zones, lake and dirty ice. Delineating changes in the distribution of differ...

Full description

Bibliographic Details
Main Author: Johnson, Erin
Format: Text
Language:unknown
Published: ScholarWorks at University of Montana 2011
Subjects:
Greenland
Isunnguata Sermia
glacier
Ice Sheet
Online Access:https://scholarworks.umt.edu/umcur/2011/oralpres1b/4
id ftunivmontana:oai:scholarworks.umt.edu:umcur-1722
record_format openpolar
spelling ftunivmontana:oai:scholarworks.umt.edu:umcur-1722 2023-07-16T03:58:34+02:00 REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET Johnson, Erin 2011-04-15T17:00:00Z https://scholarworks.umt.edu/umcur/2011/oralpres1b/4 unknown ScholarWorks at University of Montana https://scholarworks.umt.edu/umcur/2011/oralpres1b/4 University of Montana Conference on Undergraduate Research (UMCUR) text 2011 ftunivmontana 2023-06-27T23:01:43Z Climate and altitude are the primary drivers in the distribution of snow facies, ice facies and zones on the surface of the Greenland Ice Sheet. There are three different facies: ablation, percolation, and dry-snow, and two zones, lake and dirty ice. Delineating changes in the distribution of different facies and zones on glaciers through time is critical to understanding ice sheet surface processes. I seek to understand and delineate the distribution of different facies and zones on the glacier Isunnguata Sermia in Greenland for the months of May through September in 2010. To delineate the different zones and facies, I used daily Moderate Resolution Imaging Spectroradiometer (MODIS) images for the months of May through September. I downloaded bands 1-6 at 500 meter resolution, reprojected and enhanced each image by running a principle components analysis and creating RGB color composite for each day. I found that the zones moved to higher altitudes later in the summer, with August producing the overall largest change. To investigate the ice below the surface, I used video of thirteen boreholes from June and July 2010. Within the ice, there are two zones: clean ice, and debris-laden ice near the bed. I classified the ice based on clarity of the ice, and the size and amount of debris contained within it. I found that the debris-laden ice was only found within 2 meters of the bed, none was found at the surface in the study area. Text glacier Greenland Ice Sheet University of Montana: ScholarWorks Greenland Isunnguata Sermia ENVELOPE(-50.167,-50.167,67.183,67.183)
institution Open Polar
collection University of Montana: ScholarWorks
op_collection_id ftunivmontana
language unknown
description Climate and altitude are the primary drivers in the distribution of snow facies, ice facies and zones on the surface of the Greenland Ice Sheet. There are three different facies: ablation, percolation, and dry-snow, and two zones, lake and dirty ice. Delineating changes in the distribution of different facies and zones on glaciers through time is critical to understanding ice sheet surface processes. I seek to understand and delineate the distribution of different facies and zones on the glacier Isunnguata Sermia in Greenland for the months of May through September in 2010. To delineate the different zones and facies, I used daily Moderate Resolution Imaging Spectroradiometer (MODIS) images for the months of May through September. I downloaded bands 1-6 at 500 meter resolution, reprojected and enhanced each image by running a principle components analysis and creating RGB color composite for each day. I found that the zones moved to higher altitudes later in the summer, with August producing the overall largest change. To investigate the ice below the surface, I used video of thirteen boreholes from June and July 2010. Within the ice, there are two zones: clean ice, and debris-laden ice near the bed. I classified the ice based on clarity of the ice, and the size and amount of debris contained within it. I found that the debris-laden ice was only found within 2 meters of the bed, none was found at the surface in the study area.
format Text
author Johnson, Erin
spellingShingle Johnson, Erin
REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET
author_facet Johnson, Erin
author_sort Johnson, Erin
title REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET
title_short REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET
title_full REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET
title_fullStr REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET
title_full_unstemmed REMOTE SENSING OF SNOW AND ICE ALONG THE SURFACE AND TO THE BED OF THE GREENLAND ICE SHEET
title_sort remote sensing of snow and ice along the surface and to the bed of the greenland ice sheet
publisher ScholarWorks at University of Montana
publishDate 2011
url https://scholarworks.umt.edu/umcur/2011/oralpres1b/4
long_lat ENVELOPE(-50.167,-50.167,67.183,67.183)
geographic Greenland
Isunnguata Sermia
geographic_facet Greenland
Isunnguata Sermia
genre glacier
Greenland
Ice Sheet
genre_facet glacier
Greenland
Ice Sheet
op_source University of Montana Conference on Undergraduate Research (UMCUR)
op_relation https://scholarworks.umt.edu/umcur/2011/oralpres1b/4
_version_ 1771545734152192000

Similar Items