A full-Stokes 3D calving model applied to a large Greenlandic glacier

Iceberg calving accounts for around half of all mass loss from both the Greenland and Antarctic ice sheets. The diverse nature of calving and its complex links to both internal dynamics and climate make it challenging to incorporate into models of glaciers and ice sheets. Here, we present results fr...

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Published in:Journal of Geophysical Research: Earth Surface
Main Authors: Todd, Joe, Christoffersen, Poul, Zwinger, Thomas, Råback, Peter, Chauché, Nolwenn, Benn, Doug, Luckman, Adrian, Ryan, Johnny, Toberg, Nick, Slater, Donald, Hubbard, Alun
Other Authors: University of St Andrews. School of Geography & Sustainable Development, University of St Andrews. Bell-Edwards Geographic Data Institute
Format: Article in Journal/Newspaper
Language:English
Published: 2018
Subjects:
Calving
Greenland
Modelling
GE Environmental Sciences
QE Geology
DAS
GE
QE
Antarctic
Antarc*
glacier
greenlandic
Iceberg*
Online Access:http://hdl.handle.net/10023/15940
https://doi.org/10.1002/2017JF004349
id ftstandrewserep:oai:research-repository.st-andrews.ac.uk:10023/15940
record_format openpolar
spelling ftstandrewserep:oai:research-repository.st-andrews.ac.uk:10023/15940 2023-07-02T03:30:02+02:00 A full-Stokes 3D calving model applied to a large Greenlandic glacier Todd, Joe Christoffersen, Poul Zwinger, Thomas Råback, Peter Chauché, Nolwenn Benn, Doug Luckman, Adrian Ryan, Johnny Toberg, Nick Slater, Donald Hubbard, Alun University of St Andrews. School of Geography & Sustainable Development University of St Andrews. Bell-Edwards Geographic Data Institute 2018-09-01 23 application/pdf http://hdl.handle.net/10023/15940 https://doi.org/10.1002/2017JF004349 eng eng Journal of Geophysical Research - Earth Surface Todd , J , Christoffersen , P , Zwinger , T , Råback , P , Chauché , N , Benn , D , Luckman , A , Ryan , J , Toberg , N , Slater , D & Hubbard , A 2018 , ' A full-Stokes 3D calving model applied to a large Greenlandic glacier ' , Journal of Geophysical Research - Earth Surface , vol. 123 , no. 3 , pp. 410-432 . https://doi.org/10.1002/2017JF004349 2169-9011 PURE: 252216010 PURE UUID: 1cc468fb-efd8-4c86-bf02-7f59d5ce362a Bibtex: urn:e3fe5900126a4233797f4eaf5bae7c1e Scopus: 85042619467 WOS: 000430649400001 ORCID: /0000-0002-3604-0886/work/64697371 ORCID: /0000-0003-3183-043X/work/65014583 ORCID: /0000-0001-8394-6149/work/70619153 http://hdl.handle.net/10023/15940 https://doi.org/10.1002/2017JF004349 © 2018 American Geophysical Union. All Rights Reserved. This work is made available online in accordance with the publisher’s policies. This is the final published version of the work, which was originally published at: https://doi.org/10.1002/2017JF004349 Calving Greenland Modelling GE Environmental Sciences QE Geology DAS GE QE Journal article 2018 ftstandrewserep https://doi.org/10.1002/2017JF004349 2023-06-13T18:28:48Z Iceberg calving accounts for around half of all mass loss from both the Greenland and Antarctic ice sheets. The diverse nature of calving and its complex links to both internal dynamics and climate make it challenging to incorporate into models of glaciers and ice sheets. Here, we present results from a new open-source 3D full-Stokes calving model developed in Elmer/Ice. The calving model implements the crevasse depth criterion, which states that calving occurs when surface and basal crevasses penetrate the full thickness of the glacier. The model also implements a new 3D rediscretization approach and a time-evolution scheme which allow the calving front to evolve realistically through time. We test the model in an application to Store Glacier, one of the largest outlet glaciers in West Greenland, and find that it realistically simulates the seasonal advance and retreat when two principal environmental forcings are applied. These forcings are 1) submarine melting in distributed and concentrated forms, and 2) ice mélange buttressing. We find that ice mélange buttressing is primarily responsible for Store Glacier's seasonal advance and retreat. Distributed submarine melting prevents the glacier from forming a permanent floating tongue, while concentrated plume melting has a disproportionately large and potentially destabilizing effect on the calving front position. Our results also highlight the importance of basal topography, which exerts a strong control on calving, explaining why Store Glacier has remained stable during a period when neighboring glaciers have undergone prolonged interannual retreat. Publisher PDF Peer reviewed Article in Journal/Newspaper Antarc* Antarctic glacier Greenland greenlandic Iceberg* University of St Andrews: Digital Research Repository Antarctic Greenland Journal of Geophysical Research: Earth Surface 123 3 410 432
institution Open Polar
collection University of St Andrews: Digital Research Repository
op_collection_id ftstandrewserep
language English
topic Calving
Greenland
Modelling
GE Environmental Sciences
QE Geology
DAS
GE
QE
spellingShingle Calving
Greenland
Modelling
GE Environmental Sciences
QE Geology
DAS
GE
QE
Todd, Joe
Christoffersen, Poul
Zwinger, Thomas
Råback, Peter
Chauché, Nolwenn
Benn, Doug
Luckman, Adrian
Ryan, Johnny
Toberg, Nick
Slater, Donald
Hubbard, Alun
A full-Stokes 3D calving model applied to a large Greenlandic glacier
topic_facet Calving
Greenland
Modelling
GE Environmental Sciences
QE Geology
DAS
GE
QE
description Iceberg calving accounts for around half of all mass loss from both the Greenland and Antarctic ice sheets. The diverse nature of calving and its complex links to both internal dynamics and climate make it challenging to incorporate into models of glaciers and ice sheets. Here, we present results from a new open-source 3D full-Stokes calving model developed in Elmer/Ice. The calving model implements the crevasse depth criterion, which states that calving occurs when surface and basal crevasses penetrate the full thickness of the glacier. The model also implements a new 3D rediscretization approach and a time-evolution scheme which allow the calving front to evolve realistically through time. We test the model in an application to Store Glacier, one of the largest outlet glaciers in West Greenland, and find that it realistically simulates the seasonal advance and retreat when two principal environmental forcings are applied. These forcings are 1) submarine melting in distributed and concentrated forms, and 2) ice mélange buttressing. We find that ice mélange buttressing is primarily responsible for Store Glacier's seasonal advance and retreat. Distributed submarine melting prevents the glacier from forming a permanent floating tongue, while concentrated plume melting has a disproportionately large and potentially destabilizing effect on the calving front position. Our results also highlight the importance of basal topography, which exerts a strong control on calving, explaining why Store Glacier has remained stable during a period when neighboring glaciers have undergone prolonged interannual retreat. Publisher PDF Peer reviewed
author2 University of St Andrews. School of Geography & Sustainable Development
University of St Andrews. Bell-Edwards Geographic Data Institute
format Article in Journal/Newspaper
author Todd, Joe
Christoffersen, Poul
Zwinger, Thomas
Råback, Peter
Chauché, Nolwenn
Benn, Doug
Luckman, Adrian
Ryan, Johnny
Toberg, Nick
Slater, Donald
Hubbard, Alun
author_facet Todd, Joe
Christoffersen, Poul
Zwinger, Thomas
Råback, Peter
Chauché, Nolwenn
Benn, Doug
Luckman, Adrian
Ryan, Johnny
Toberg, Nick
Slater, Donald
Hubbard, Alun
author_sort Todd, Joe
title A full-Stokes 3D calving model applied to a large Greenlandic glacier
title_short A full-Stokes 3D calving model applied to a large Greenlandic glacier
title_full A full-Stokes 3D calving model applied to a large Greenlandic glacier
title_fullStr A full-Stokes 3D calving model applied to a large Greenlandic glacier
title_full_unstemmed A full-Stokes 3D calving model applied to a large Greenlandic glacier
title_sort full-stokes 3d calving model applied to a large greenlandic glacier
publishDate 2018
url http://hdl.handle.net/10023/15940
https://doi.org/10.1002/2017JF004349
geographic Antarctic
Greenland
geographic_facet Antarctic
Greenland
genre Antarc*
Antarctic
glacier
Greenland
greenlandic
Iceberg*
genre_facet Antarc*
Antarctic
glacier
Greenland
greenlandic
Iceberg*
op_relation Journal of Geophysical Research - Earth Surface
Todd , J , Christoffersen , P , Zwinger , T , Råback , P , Chauché , N , Benn , D , Luckman , A , Ryan , J , Toberg , N , Slater , D & Hubbard , A 2018 , ' A full-Stokes 3D calving model applied to a large Greenlandic glacier ' , Journal of Geophysical Research - Earth Surface , vol. 123 , no. 3 , pp. 410-432 . https://doi.org/10.1002/2017JF004349
2169-9011
PURE: 252216010
PURE UUID: 1cc468fb-efd8-4c86-bf02-7f59d5ce362a
Bibtex: urn:e3fe5900126a4233797f4eaf5bae7c1e
Scopus: 85042619467
WOS: 000430649400001
ORCID: /0000-0002-3604-0886/work/64697371
ORCID: /0000-0003-3183-043X/work/65014583
ORCID: /0000-0001-8394-6149/work/70619153
http://hdl.handle.net/10023/15940
https://doi.org/10.1002/2017JF004349
op_rights © 2018 American Geophysical Union. All Rights Reserved. This work is made available online in accordance with the publisher’s policies. This is the final published version of the work, which was originally published at: https://doi.org/10.1002/2017JF004349
op_doi https://doi.org/10.1002/2017JF004349
container_title Journal of Geophysical Research: Earth Surface
container_volume 123
container_issue 3
container_start_page 410
op_container_end_page 432
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