Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015
This project focused on analyzing brine network structure in first year Arctic sea ice (samples collected during a 2015 field campaign), to collect data which could be used to develop applied mathematical methods to describe brine network structure in first year Arctic Sea Ice. A large part of the p...
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Arctic Data Center
2015
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| Online Access: | https://search.dataone.org/view/urn:uuid:b8b0dd97-0b57-40ae-b0ce-dcb1e91f3692 |
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openpolar |
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dataone:urn:uuid:b8b0dd97-0b57-40ae-b0ce-dcb1e91f3692 2024-06-03T18:46:40+00:00 Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 Rachel Obbard Scott Pauls Ross Lieb-Lappen Utquiagvik (Barrow), Alaska ENVELOPE(-156.7886,-156.7886,71.29056,71.29056) BEGINDATE: 2013-09-01T00:00:00Z ENDDATE: 2016-08-31T00:00:00Z 2015-01-01T00:00:00Z https://search.dataone.org/view/urn:uuid:b8b0dd97-0b57-40ae-b0ce-dcb1e91f3692 unknown Arctic Data Center Sea Ice Ice Depth/Thickness Ice Growth/Melt Ice Types Dataset 2015 dataone:urn:node:ARCTIC 2024-06-03T18:11:32Z This project focused on analyzing brine network structure in first year Arctic sea ice (samples collected during a 2015 field campaign), to collect data which could be used to develop applied mathematical methods to describe brine network structure in first year Arctic Sea Ice. A large part of the project was the design of a Temperature Gradient Ice Core Transport System (TGICTS), named the ICE-MITT, with which we could transport cores from the field back to our lab at in-situ temperature gradients. This was partially successful. We discovered that improvements needed to be made to the design of the device if it is to work for large cores (ours were 1 m x 14 cm diameter) and at non-freezing ambient temperatures. A freezer failure at Dartmouth resulted in the loss of the cores that were transported with this device, leaving us with only cores that had been shipped back the traditional (isothermal) method (at a uniform -20C). Samples from the "isothermal" cores were taken every 10 cm and analyzed using X-ray micro computed tomography in a -14C cold room. We identified a set of metrics that can be gleaned from X-ray micro-computed tomography and are useful for interpreting the microstructure of sea ice (Lieb-Lappen et al., 2017). We have used these to quantify some differences in brine channel topology with depth, and some differences between granular and frazil ice. Finally, we tested the Notz wire harp by cutting a hole in the ice cover in late February 2015 and freezing the harp into it. Based on the principle that pure solid ice is a good insulator whereas interstitial saltwater brine is a good conductor, the device developed by Notz, Worster and Wettlaufer (Notz et al., 2005; Notz and Worster, 2008) records temperature and resistivity at different depths as ice grows around it. Salinity of the interstitial brine is then inferred from the liquidus relationship (Cox and Weeks, 1986) and can be combined with the measured solid mass fraction to give the bulk salinity profile of the growing sea ice. This was a preliminary test for later use of the harp on another project. Dataset Arctic Barrow ice core Sea ice Alaska Lappen Arctic Data Center (via DataONE) Arctic Lappen ENVELOPE(15.774,15.774,67.959,67.959) ENVELOPE(-156.7886,-156.7886,71.29056,71.29056) |
| institution |
Open Polar |
| collection |
Arctic Data Center (via DataONE) |
| op_collection_id |
dataone:urn:node:ARCTIC |
| language |
unknown |
| topic |
Sea Ice Ice Depth/Thickness Ice Growth/Melt Ice Types |
| spellingShingle |
Sea Ice Ice Depth/Thickness Ice Growth/Melt Ice Types Rachel Obbard Scott Pauls Ross Lieb-Lappen Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 |
| topic_facet |
Sea Ice Ice Depth/Thickness Ice Growth/Melt Ice Types |
| description |
This project focused on analyzing brine network structure in first year Arctic sea ice (samples collected during a 2015 field campaign), to collect data which could be used to develop applied mathematical methods to describe brine network structure in first year Arctic Sea Ice. A large part of the project was the design of a Temperature Gradient Ice Core Transport System (TGICTS), named the ICE-MITT, with which we could transport cores from the field back to our lab at in-situ temperature gradients. This was partially successful. We discovered that improvements needed to be made to the design of the device if it is to work for large cores (ours were 1 m x 14 cm diameter) and at non-freezing ambient temperatures. A freezer failure at Dartmouth resulted in the loss of the cores that were transported with this device, leaving us with only cores that had been shipped back the traditional (isothermal) method (at a uniform -20C). Samples from the "isothermal" cores were taken every 10 cm and analyzed using X-ray micro computed tomography in a -14C cold room. We identified a set of metrics that can be gleaned from X-ray micro-computed tomography and are useful for interpreting the microstructure of sea ice (Lieb-Lappen et al., 2017). We have used these to quantify some differences in brine channel topology with depth, and some differences between granular and frazil ice. Finally, we tested the Notz wire harp by cutting a hole in the ice cover in late February 2015 and freezing the harp into it. Based on the principle that pure solid ice is a good insulator whereas interstitial saltwater brine is a good conductor, the device developed by Notz, Worster and Wettlaufer (Notz et al., 2005; Notz and Worster, 2008) records temperature and resistivity at different depths as ice grows around it. Salinity of the interstitial brine is then inferred from the liquidus relationship (Cox and Weeks, 1986) and can be combined with the measured solid mass fraction to give the bulk salinity profile of the growing sea ice. This was a preliminary test for later use of the harp on another project. |
| format |
Dataset |
| author |
Rachel Obbard Scott Pauls Ross Lieb-Lappen |
| author_facet |
Rachel Obbard Scott Pauls Ross Lieb-Lappen |
| author_sort |
Rachel Obbard |
| title |
Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 |
| title_short |
Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 |
| title_full |
Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 |
| title_fullStr |
Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 |
| title_full_unstemmed |
Landfast Sea Ice at Utquiagvik (Barrow), Alaska in March 2015 |
| title_sort |
landfast sea ice at utquiagvik (barrow), alaska in march 2015 |
| publisher |
Arctic Data Center |
| publishDate |
2015 |
| url |
https://search.dataone.org/view/urn:uuid:b8b0dd97-0b57-40ae-b0ce-dcb1e91f3692 |
| op_coverage |
Utquiagvik (Barrow), Alaska ENVELOPE(-156.7886,-156.7886,71.29056,71.29056) BEGINDATE: 2013-09-01T00:00:00Z ENDDATE: 2016-08-31T00:00:00Z |
| long_lat |
ENVELOPE(15.774,15.774,67.959,67.959) ENVELOPE(-156.7886,-156.7886,71.29056,71.29056) |
| geographic |
Arctic Lappen |
| geographic_facet |
Arctic Lappen |
| genre |
Arctic Barrow ice core Sea ice Alaska Lappen |
| genre_facet |
Arctic Barrow ice core Sea ice Alaska Lappen |
| _version_ |
1800869466328793088 |