Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited

Our overarching goal is to understand how small-scale obstructions such as ice rises and ice rumples influence large-scale ice-shelf flow and discharge of inland ice. Here we propose to revisit CIR (Fig. 2) with new tools (radars and seismic instruments, and high-precision GPS) and make targeted geo...

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Bibliographic Details
Main Author: Paul Winberry
Format: Dataset
Language:unknown
Published: International Federation of Digital Seismograph Networks 2015
Subjects:
Ross Sea
Pine Island Glacier
Mercer
Whillans
Whillans Ice Stream
Crary Ice Rise
Ice Shelf
Online Access:https://dx.doi.org/10.7914/sn/9j_2015
https://www.fdsn.org/networks/detail/9J_2015/
id ftdatacite:10.7914/sn/9j_2015
record_format openpolar
spelling ftdatacite:10.7914/sn/9j_2015 2023-05-15T16:41:56+02:00 Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited Paul Winberry 2015 SEED data https://dx.doi.org/10.7914/sn/9j_2015 https://www.fdsn.org/networks/detail/9J_2015/ unknown International Federation of Digital Seismograph Networks dataset Dataset Seismic Network 2015 ftdatacite https://doi.org/10.7914/sn/9j_2015 2021-11-05T12:55:41Z Our overarching goal is to understand how small-scale obstructions such as ice rises and ice rumples influence large-scale ice-shelf flow and discharge of inland ice. Here we propose to revisit CIR (Fig. 2) with new tools (radars and seismic instruments, and high-precision GPS) and make targeted geophysical measurements both on the ice rise, and where possible, across the grounding line. Our measurements, together with data collected during IGY, RIGGS, SCP, as well as new data collected recently by others from the Whillans ice plain, and satellite-derived products (patterns of thinning/thickening from ICESat, and surface velocities), will be used to validate and develop models of the evolution of grounding line dynamics of the Ross Sea Embayment. The models will be used to address the following: 1. What dynamical effect does the presence/absence of CIR have on discharge of inland ice through the Ross ice streams today? In particular, is it contributing to the observed slow-down of Whillans Ice Stream? What is its influence on Mercer and Kamb Ice Streams? 2. What caused CIR to freeze to the bed 1100 years ago? Was it a response to changes in discharge of the ice streams, or was it in response to regional relative sea-level lowering caused by glacial isostatic adjustment? How does the timing of freeze-on relate to the observations that indicate grounding-line retreat in the Ross Embayment stopped ~2000 years ago? 3. What history of ice dynamics is preserved in the radar-detected internal stratigraphy? 4. How has CIR evolved over timescales ranging from: the past 35 years since the last major field campaigns; the past millennia after the freeze-on of CIR; through the deglaciation. 5. How will CIR respond to future possible environmental changes such as sea-level rise and/or ocean warming? Will it be subsumed when the grounding line advances, or will it vanish, as occurred recently to an ice rumple when the shelf in front of Pine Island Glacier melted and thinned. Dataset Ice Shelf Pine Island Glacier Ross Sea Whillans Ice Stream DataCite Metadata Store (German National Library of Science and Technology) Ross Sea Pine Island Glacier ENVELOPE(-101.000,-101.000,-75.000,-75.000) Mercer ENVELOPE(65.647,65.647,-70.227,-70.227) Whillans ENVELOPE(-64.250,-64.250,-84.450,-84.450) Whillans Ice Stream ENVELOPE(-145.000,-145.000,-83.667,-83.667) Crary Ice Rise ENVELOPE(-172.500,-172.500,-82.933,-82.933)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
description Our overarching goal is to understand how small-scale obstructions such as ice rises and ice rumples influence large-scale ice-shelf flow and discharge of inland ice. Here we propose to revisit CIR (Fig. 2) with new tools (radars and seismic instruments, and high-precision GPS) and make targeted geophysical measurements both on the ice rise, and where possible, across the grounding line. Our measurements, together with data collected during IGY, RIGGS, SCP, as well as new data collected recently by others from the Whillans ice plain, and satellite-derived products (patterns of thinning/thickening from ICESat, and surface velocities), will be used to validate and develop models of the evolution of grounding line dynamics of the Ross Sea Embayment. The models will be used to address the following: 1. What dynamical effect does the presence/absence of CIR have on discharge of inland ice through the Ross ice streams today? In particular, is it contributing to the observed slow-down of Whillans Ice Stream? What is its influence on Mercer and Kamb Ice Streams? 2. What caused CIR to freeze to the bed 1100 years ago? Was it a response to changes in discharge of the ice streams, or was it in response to regional relative sea-level lowering caused by glacial isostatic adjustment? How does the timing of freeze-on relate to the observations that indicate grounding-line retreat in the Ross Embayment stopped ~2000 years ago? 3. What history of ice dynamics is preserved in the radar-detected internal stratigraphy? 4. How has CIR evolved over timescales ranging from: the past 35 years since the last major field campaigns; the past millennia after the freeze-on of CIR; through the deglaciation. 5. How will CIR respond to future possible environmental changes such as sea-level rise and/or ocean warming? Will it be subsumed when the grounding line advances, or will it vanish, as occurred recently to an ice rumple when the shelf in front of Pine Island Glacier melted and thinned.
format Dataset
author Paul Winberry
spellingShingle Paul Winberry
Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited
author_facet Paul Winberry
author_sort Paul Winberry
title Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited
title_short Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited
title_full Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited
title_fullStr Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited
title_full_unstemmed Collaborative Research: Grounding Line Dynamics: Crary Ice Rise Revisited
title_sort collaborative research: grounding line dynamics: crary ice rise revisited
publisher International Federation of Digital Seismograph Networks
publishDate 2015
url https://dx.doi.org/10.7914/sn/9j_2015
https://www.fdsn.org/networks/detail/9J_2015/
long_lat ENVELOPE(-101.000,-101.000,-75.000,-75.000)
ENVELOPE(65.647,65.647,-70.227,-70.227)
ENVELOPE(-64.250,-64.250,-84.450,-84.450)
ENVELOPE(-145.000,-145.000,-83.667,-83.667)
ENVELOPE(-172.500,-172.500,-82.933,-82.933)
geographic Ross Sea
Pine Island Glacier
Mercer
Whillans
Whillans Ice Stream
Crary Ice Rise
geographic_facet Ross Sea
Pine Island Glacier
Mercer
Whillans
Whillans Ice Stream
Crary Ice Rise
genre Ice Shelf
Pine Island Glacier
Ross Sea
Whillans Ice Stream
genre_facet Ice Shelf
Pine Island Glacier
Ross Sea
Whillans Ice Stream
op_doi https://doi.org/10.7914/sn/9j_2015
_version_ 1766032397421248512

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