A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets

Offline forcing methods for ice-sheet models often make use of an index approach in which temperature anomalies relative to the present are calculated by combining a simulated glacial–interglacial climatic anomaly field, interpolated through an index derived from the Greenland ice-core temperature r...

Full description

Bibliographic Details
Published in:Geoscientific Model Development
Main Authors: Banderas, Rubén, Alvarez-Solas, Jorge, Robinson, Alexander, Montoya, Marisa
Format: Text
Language:English
Published: 2019
Subjects:
Online Access:https://doi.org/10.5194/gmd-11-2299-2018
https://gmd.copernicus.org/articles/11/2299/2018/
id ftcopernicus:oai:publications.copernicus.org:gmd60083
record_format openpolar
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description Offline forcing methods for ice-sheet models often make use of an index approach in which temperature anomalies relative to the present are calculated by combining a simulated glacial–interglacial climatic anomaly field, interpolated through an index derived from the Greenland ice-core temperature reconstruction, with present-day climatologies. An important drawback of this approach is that it clearly misrepresents climate variability at millennial timescales. The reason for this is that the spatial glacial–interglacial anomaly field used is associated with orbital climatic variations, while it is scaled following the characteristic time evolution of the index, which includes orbital and millennial-scale climate variability. The spatial patterns of orbital and millennial variability are clearly not the same, as indicated by a wealth of models and data. As a result, this method can be expected to lead to a misrepresentation of climate variability and thus of the past evolution of Northern Hemisphere (NH) ice sheets. Here we illustrate the problems derived from this approach and propose a new offline climate forcing method that attempts to better represent the characteristic pattern of millennial-scale climate variability by including an additional spatial anomaly field associated with this timescale. To this end, three different synthetic transient forcing climatologies are developed for the past 120 kyr following a perturbative approach and are applied to an ice-sheet model. The impact of the climatologies on the paleo-evolution of the NH ice sheets is evaluated. The first method follows the usual index approach in which temperature anomalies relative to the present are calculated by combining a simulated glacial–interglacial climatic anomaly field, interpolated through an index derived from ice-core data, with present-day climatologies. In the second approach the representation of millennial-scale climate variability is improved by incorporating a simulated stadial–interstadial anomaly field. The third is a refinement of the second one in which the amplitudes of both orbital and millennial-scale variations are tuned to provide perfect agreement with a recently published absolute temperature reconstruction over Greenland. The comparison of the three climate forcing methods highlights the tendency of the usual index approach to overestimate the temperature variability over North America and Eurasia at millennial timescales. This leads to a relatively high NH ice-volume variability on these timescales. Through enhanced ablation, this results in too low an ice volume throughout the last glacial period (LGP), below or at the lower end of the uncertainty range of estimations. Improving the representation of millennial-scale variability alone yields an important increase in ice volume in all NH ice sheets but especially in the Fennoscandian Ice Sheet (FIS). Optimizing the amplitude of the temperature anomalies to match the Greenland reconstruction results in a further increase in the simulated ice-sheet volume throughout the LGP. Our new method provides a more realistic representation of orbital and millennial-scale climate variability and improves the transient forcing of ice sheets during the LGP. Interestingly, our new approach underestimates ice-volume variations on millennial timescales as indicated by sea-level records. This suggests that either the origin of the latter is not the NH or that processes not represented in our study, notably variations in oceanic conditions, need to be invoked to explain millennial-scale ice-volume fluctuations. We finally provide here both our derived climate evolution of the LGP using the three methods as well as the resulting ice-sheet configurations. These could be of interest for future studies dealing with the atmospheric or/and oceanic consequences of transient ice-sheet evolution throughout the LGP and as a source of climate input to other ice-sheet models.
format Text
author Banderas, Rubén
Alvarez-Solas, Jorge
Robinson, Alexander
Montoya, Marisa
spellingShingle Banderas, Rubén
Alvarez-Solas, Jorge
Robinson, Alexander
Montoya, Marisa
A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets
author_facet Banderas, Rubén
Alvarez-Solas, Jorge
Robinson, Alexander
Montoya, Marisa
author_sort Banderas, Rubén
title A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets
title_short A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets
title_full A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets
title_fullStr A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets
title_full_unstemmed A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets
title_sort new approach for simulating the paleo-evolution of the northern hemisphere ice sheets
publishDate 2019
url https://doi.org/10.5194/gmd-11-2299-2018
https://gmd.copernicus.org/articles/11/2299/2018/
geographic Greenland
geographic_facet Greenland
genre Fennoscandian
Greenland
Greenland ice core
ice core
Ice Sheet
genre_facet Fennoscandian
Greenland
Greenland ice core
ice core
Ice Sheet
op_source eISSN: 1991-9603
op_relation doi:10.5194/gmd-11-2299-2018
https://gmd.copernicus.org/articles/11/2299/2018/
op_doi https://doi.org/10.5194/gmd-11-2299-2018
container_title Geoscientific Model Development
container_volume 11
container_issue 6
container_start_page 2299
op_container_end_page 2314
_version_ 1765998832323133440
spelling ftcopernicus:oai:publications.copernicus.org:gmd60083 2023-05-15T16:13:12+02:00 A new approach for simulating the paleo-evolution of the Northern Hemisphere ice sheets Banderas, Rubén Alvarez-Solas, Jorge Robinson, Alexander Montoya, Marisa 2019-01-29 application/pdf https://doi.org/10.5194/gmd-11-2299-2018 https://gmd.copernicus.org/articles/11/2299/2018/ eng eng doi:10.5194/gmd-11-2299-2018 https://gmd.copernicus.org/articles/11/2299/2018/ eISSN: 1991-9603 Text 2019 ftcopernicus https://doi.org/10.5194/gmd-11-2299-2018 2020-07-20T16:23:13Z Offline forcing methods for ice-sheet models often make use of an index approach in which temperature anomalies relative to the present are calculated by combining a simulated glacial–interglacial climatic anomaly field, interpolated through an index derived from the Greenland ice-core temperature reconstruction, with present-day climatologies. An important drawback of this approach is that it clearly misrepresents climate variability at millennial timescales. The reason for this is that the spatial glacial–interglacial anomaly field used is associated with orbital climatic variations, while it is scaled following the characteristic time evolution of the index, which includes orbital and millennial-scale climate variability. The spatial patterns of orbital and millennial variability are clearly not the same, as indicated by a wealth of models and data. As a result, this method can be expected to lead to a misrepresentation of climate variability and thus of the past evolution of Northern Hemisphere (NH) ice sheets. Here we illustrate the problems derived from this approach and propose a new offline climate forcing method that attempts to better represent the characteristic pattern of millennial-scale climate variability by including an additional spatial anomaly field associated with this timescale. To this end, three different synthetic transient forcing climatologies are developed for the past 120 kyr following a perturbative approach and are applied to an ice-sheet model. The impact of the climatologies on the paleo-evolution of the NH ice sheets is evaluated. The first method follows the usual index approach in which temperature anomalies relative to the present are calculated by combining a simulated glacial–interglacial climatic anomaly field, interpolated through an index derived from ice-core data, with present-day climatologies. In the second approach the representation of millennial-scale climate variability is improved by incorporating a simulated stadial–interstadial anomaly field. The third is a refinement of the second one in which the amplitudes of both orbital and millennial-scale variations are tuned to provide perfect agreement with a recently published absolute temperature reconstruction over Greenland. The comparison of the three climate forcing methods highlights the tendency of the usual index approach to overestimate the temperature variability over North America and Eurasia at millennial timescales. This leads to a relatively high NH ice-volume variability on these timescales. Through enhanced ablation, this results in too low an ice volume throughout the last glacial period (LGP), below or at the lower end of the uncertainty range of estimations. Improving the representation of millennial-scale variability alone yields an important increase in ice volume in all NH ice sheets but especially in the Fennoscandian Ice Sheet (FIS). Optimizing the amplitude of the temperature anomalies to match the Greenland reconstruction results in a further increase in the simulated ice-sheet volume throughout the LGP. Our new method provides a more realistic representation of orbital and millennial-scale climate variability and improves the transient forcing of ice sheets during the LGP. Interestingly, our new approach underestimates ice-volume variations on millennial timescales as indicated by sea-level records. This suggests that either the origin of the latter is not the NH or that processes not represented in our study, notably variations in oceanic conditions, need to be invoked to explain millennial-scale ice-volume fluctuations. We finally provide here both our derived climate evolution of the LGP using the three methods as well as the resulting ice-sheet configurations. These could be of interest for future studies dealing with the atmospheric or/and oceanic consequences of transient ice-sheet evolution throughout the LGP and as a source of climate input to other ice-sheet models. Text Fennoscandian Greenland Greenland ice core ice core Ice Sheet Copernicus Publications: E-Journals Greenland Geoscientific Model Development 11 6 2299 2314